TWI551572B - Compositions and methods of making and using the compositions for improving soil and/or plant growth and improved soil, improved plants, and/or improved seeds - Google Patents

Description

Composition for improving soil and/or plant growth and methods of making and using the same, and improved soil, improved plants and/or improved seeds

The present disclosure relates to novel compositions for improving the quality of soil, plant growth, seeds and/or plant products, and methods of making and using the same, and improved soil, improved plants, improved seeds and / or improved plant products.

Many terrestrials provide soil that cannot support the growth of food plants and other agricultural products or support the growth of such plants and other products. Therefore, the lack of food and other agricultural products is a problem worldwide. And some parts of the world do not have enough water (especially no salt water) to irrigate these plants and other products.

Conventionally, crop rotation and fertilizer are the main countermeasures used by humans to improve the productivity of food plants and other agricultural products. However, the benefits arising from crop rotation and fertilizer can be limited. For example, the amount of fertilizer applied to the field will need to increase year by year to maintain productivity or use excessive amounts of fertilizer, which can lead to, for example, soil hardening, salinization, pollution to the environment (such as soil), and degradation of plant and plant products. The problem. Of course, there is a great desire to improve plant growth everywhere, especially in areas where the soil requires more than enough supply of agricultural products.

The present inventors have discovered novel compositions for practical use and methods of making and using the compositions, such as, in certain embodiments, to improve the quality of soil, plant growth, seeds, and/or plant products. At least one of the questions raised above. The inventors have also discovered improved soils including improved soils prepared by the methods disclosed herein; modified plants, modified plants made by the methods disclosed herein; Improved seed, improved seed produced by the method disclosed herein; and improved plant product, including improved quality of the plant product, and improved by the methods disclosed herein Plant products.

Simple illustration

Figure 1 shows an international soil texture triangle for the classification of certain soil types.

Figure 2 shows a flow chart of a method for making a composition according to one embodiment of the present disclosure.

Figure 3 shows a flow chart of a method for making a composition according to another embodiment of the present disclosure.

Figures 4A and 4B show a flow chart of a method for making a composition according to still another embodiment of the present disclosure.

Figure 5 shows the relative energy state values for N, P and K comparing the effects of the compositions according to the present disclosure with other conventional fertilizers. Figure 5A shows the relative energy state of the N values in the following materials: LangFang soil samples alone (soil), composition according to the present disclosure alone (BGA1), urea alone (urea), diammonium phosphate alone ( (NH ₄ ) ₂ HPO ₄ ), Sierte brand of sulfur-based high-concentration compound fertilizer alone (available from Anhui Sierte Fertilizer Company, Ltd.) Commercially available) (fertilizer), 1:1 weight of Langfang soil sample plus BGA1 mixture (soil + BGA1), 1:1 weight of Langfang soil sample plus urea mixture (soil + urea), 1:1 by weight of Langfang soil sample plus a mixture of diammonium phosphate (soil + (NH ₄ ) ₂ HPO ₄ ) and a 1:1 weight of Langfang soil sample plus a mixture of high-concentration compound fertilizer (soil + fertilizer). Figure 5B shows the relative energy states of P values in the following materials: Langfang soil samples alone (soil), BGA1 alone (BGA1), diammonium phosphate alone ((NH ₄ ) ₂ HPO ₄ ), Sylt Sulfur-based high-concentration compound fertilizer (see above) alone (fertilizer), 1:1 weight of Langfang soil sample plus BGA1 mixture (soil + BGA1), 1:1 weight of Langfang soil sample plus A mixture of diammonium phosphate (soil + (NH ₄ ) ₂ HPO ₄ ) and a 1:1 weight of Langfang soil sample plus a mixture of high-concentration compound fertilizer (soil + fertilizer). Figure 5C shows the relative energy state of K values in the following materials: Langfang soil samples alone (soil), BGA1 alone (BGA1), potassium sulfate alone (K ₂ SO ₄ ), and Sylt's sulfur-based High-concentration compound fertilizer (see above) alone (fertilizer), 1:1 weight of Langfang soil sample plus BGA1 mixture (soil + BGA1), 1:1 weight of Langfang soil sample plus potassium sulfate Mixture (soil + K ₂ SO ₄ ) and a 1:1 weight of Langfang soil sample plus a mixture of high-concentration compound fertilizer (soil + fertilizer).

Figure 6 shows a desert sand sample (indicated as "untreated") not treated with the composition according to the present disclosure and a desert sand sample (indicated as "treatment") treated with the composition according to the present disclosure. Relative energy state values of N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, and Mo.

Figure 7A shows the energy spectrum of a desert sand sample not treated with the composition according to the present disclosure. Figure 7B shows the energy spectrum of a desert sand sample treated with the composition according to the present disclosure.

Figure 8 shows the relative energy state values of Cl in the following materials: saline-alkaline soil sample (saline-alkali soil), composition according to the present disclosure (BGA4), high-concentration compound fertilizer without Cl (Silte brand) Sulfur-based high-concentration compound fertilizer, commercially available from Anhui Sierte Fertilizer Co., Ltd.) (CF), high-concentration compound fertilizer containing Cl (Silter-based chlorine-based high-concentration compound fertilizer (commercially available from China's Anhui Silter Fertilizer Company) (CFCl), 1:1 weight of saline-alkaline soil sample plus BGA4 mixture (S+BGA4), 1:1 saline-alkali soil sample plus a mixture of high-concentration compound fertilizer without Cl (S+CF), a 1:1 weight-to-salt saline soil sample plus a mixture of high-concentration compound fertilizer containing Cl (S+CFCl) and 1:1:1 A saline-alkaline soil sample of the weight plus a mixture of high-concentration compound fertilizer containing Cl and BGA4 (S+CFCl+BGA4).

Figures 9A-9F show a complete commercially available device containing software that is used to measure as found in soil treated with BGA5 decades ago and as in Example 8 as it was decades ago. Describe the relative energy state values of the nourishing elements (such as N, P, and K) found in the soil that is fertilized.

Figures 10A and 10B show a complete commercially available device comprising a soft body for measuring the energy spectrum of a composition, soil and/or plant as disclosed herein.

Figure 11 graphically shows a coil wound around a container, wherein the coil is used to generate an electromagnetic field by flowing an AC current therethrough to process at least one material in the container.

Figure 12A shows the particle size distribution of sand/loamy sand that has not been treated with BGA2. Figure 12B shows the particle size distribution of sandy loam obtained by treating sand/loamy sand with BGA2. Figure 12C shows that in the international soil texture triangulation used for soil classification, the sand/loamy sand soil not treated with BGA2 is at point A, and is shown to be treated with BGA2 sand/sediment sand. The obtained sandy loam is at point B. Those patterns are related to the experiments reported in Example 4.

In one aspect, the present disclosure relates to a composition such as, for example, a composition comprising at least one nourishing element; a composition comprising at least one photosensitive material comprising at least one nourishing element; comprising at least one organic acidic substance ( a composition comprising at least one nourishing element; a composition comprising a first composition comprising at least one organic acid and a second composition comprising at least one photosensitive material, wherein the first time At least one of the composition and the second composition comprises at least one nourishing element; comprising a first composition comprising at least one organic acidic substance comprising at least one first nourishing element and a second composition comprising a composition of at least one photosensitive material comprising at least one second nourishing element; and comprising about 15% of the first composition (which comprises at least one first nourishing element) and about 15% of the second composition a composition of (including at least one second nourishing element) and about 70% of a third composition (which selectively comprises at least one third nourishing element) in relation to By weight of the total weight of the composition meter.

In certain embodiments, the at least one nourishing element in the composition as disclosed herein has a relative energy state value that is greater than the value of at least one nourishing element in a pre-existing state in those compositions. Not limited by theory, larger relative energy state values are sufficient (eg, sufficient values and reserved for a sufficient period of time) to improve soil, plant, plant growth, seed, seed quality, and plant products (including improved plant products) quality). In certain embodiments, not limited by theory, a larger relative energy state value is sufficient for the composition to improve soil (including virgin soil, when combined with the composition) to support plant growth, which is less than the soil Good combination with the composition. In some embodiments, again, not by theory, a larger relative energy state value is sufficient to allow the composition to be selected from sand/loar sand (such as river sand), heavy clay, clay, sand. The soil of clay, sandy clay loam, silty clay, silty clay loam and silt loam is converted into modified soil selected from sandy loam, loamy clay, clay loam and loam, when the soil is When the composition is combined. In some embodiments, again, not by theory, a large relative energy state value is sufficient to allow the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth. And compared to the soil when not combined with the composition.

In some specific examples (see Examples 1-14 (eg, BGA1-BGA6) using energy-treated compositions, energy-treated fertilizers, including 15-15-15 fertilizers and urea), one is disclosed A method for treating soil comprising: contacting the soil with an effective amount of the energy-treated composition, wherein the composition comprises at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than the a relative energy state value of at least one nourishing element in a pre-existing state, the composition effective to improve the ability of the soil (when combined with the effective amount of the composition) to support plant growth, which is not the composition of the soil Good combination.

In certain embodiments, a method for treating soil is disclosed, comprising: contacting the soil with an effective amount of the energy-treated composition, wherein the composition comprises at least one nourishing element, wherein the at least one The relative energy state value possessed by the nourishing element is greater than the relative energy state value of the at least one nourishing element in the pre-existing state, the composition effectively improving the soil (when combined with the effective amount of the composition) all or part of the brine The ability to irrigate to support plant growth is compared to when the soil is not combined with the composition.

In some embodiments, a method for treating soil is disclosed, comprising: contacting the soil with an effective amount of an energy-treated composition, wherein the composition comprises: a composition comprising at least one organic acid a first composition, a second composition comprising at least one photosensitive material, wherein at least one of the first composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitivity The substance is different from the at least one organic acid substance, and a third composition comprising at least one organic base material, wherein the organic base material selectively comprises at least one third nourishing element, the at least one organic basic substance The at least one organic acidic substance and the at least one photosensitive substance are different, wherein the at least one first and third nourishing elements may be the same or different, and further wherein a relative energy state possessed by at least one of the first and third nourishing elements a value greater than a relative energy state of at least one of the first and third nourishing elements in the pre-existing state Hershey effectively improve the composition of the soil (when combined with an effective amount of the composition) the ability to support plant growth, which, when not bound to the composition ratio of the soil.

In some embodiments, a method for treating soil is disclosed, comprising: contacting the soil with an effective amount of an energy-treated composition, wherein the composition comprises: a composition comprising at least one organic acid a first composition, a second composition comprising at least one photosensitive material, wherein at least one of the first composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitivity The substance is different from the at least one organic acid substance, and a third composition comprising at least one organic base material, the organic base material selectively comprising at least one third nourishing element, the at least one organic basic substance being associated with the at least one organic basic substance An organic acidic substance and at least one photosensitive substance, wherein the at least one first and third nourishing elements may be the same or different, and further wherein at least one of the first and third nourishing elements has a relative energy state value greater than a relative energy state value of at least one of the first and third nourishing elements in a pre-existing state, Improvement of the soil was as effective (when combined with an effective amount of the composition) wholly or partly of saline irrigation to the ability to support plant growth, compared with the case when the soil is not combined with the composition.

In some embodiments, a method for treating soil is disclosed, comprising: contacting the soil with an effective amount of an energy-treated composition, wherein the composition comprises: a composition comprising at least one organic acid a first composition, the organic acidic substance comprising at least one first nourishing element, a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishing element, the at least one photosensitive substance Is different from the at least one organic acidic substance, and a third composition comprising at least one organic basic substance, the organic basic substance selectively comprising at least one third nourishing element, the at least one organic basic substance and the at least one The organic acidic substance and the at least one photosensitive substance are different, wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements possesses The relative energy state value is greater than at least the first, second, and third nourishing elements in the pre-existing state Relative energy state thereof, effectively improve the composition of the soil (when combined with an effective amount of the composition) the ability to support plant growth, as well as it is not combined with the composition ratio of the soil.

In some embodiments, a method for treating soil is disclosed, comprising: contacting the soil with an effective amount of the energy-treated composition, wherein the composition comprises: a first comprising at least one organic acid a primary composition, the organic acidic substance comprising at least one first nourishing element, a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishing element, the at least one photosensitive substance Different from the at least one organic acidic substance, and a third composition comprising at least one organic basic substance, the organic basic substance selectively comprising at least one third nourishing element, the at least one organic basic substance and the at least one organic The acidic substance and the at least one photosensitive substance are different, wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein the relative possession of at least one of the first, second and third nourishing elements The energy state value is greater than at least one of the first, second, and third nourishing elements in the pre-existing state Relative energy state, effectively improve the composition of the soil (when combined with an effective amount of the composition) of irrigation by saline to the ability to support plant growth, compared with the case when the soil is not combined with the composition.

In certain embodiments, a method for improving plant growth is disclosed, comprising: contacting the plant with an effective amount of the energy-treated composition for a sufficient period of time, wherein the composition comprises: a first composition of an organic acidic substance, the organic acidic substance comprising at least one first nourishing element, and/or a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishment An element, the at least one photosensitive material being different from the at least one organic acidic substance, wherein the at least one first and second nourishing elements may be the same or different, and further wherein at least one of the first and second nourishing elements is possessed The relative energy state value is greater than a relative energy state value of at least one of the first and second nourishing elements in the pre-existing state.

In certain embodiments, a method for treating soil is disclosed, comprising: contacting the soil with an effective amount of the energy-treated composition, wherein the composition comprises at least one nourishing element, and further wherein The energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in the pre-existing state, the composition effectively improving the ability of the soil (when combined with the effective amount of the composition) to support plant growth, which is greater than the soil Good when not combined with the composition.

In certain embodiments, a method for treating soil is disclosed, comprising: contacting the soil with an effective amount of the energy-treated composition, wherein the composition comprises at least one nourishing element, and further wherein The energy spectrum possessed by the composition is more positive than the energy spectrum of the pre-existing composition, which is effective to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, Compare with the soil when not combined with the composition.

In some embodiments, there is disclosed a method for treating soil that does not support the growth of horticultural and/or agricultural plants, such as desert sand, to convert the soil into soil capable of supporting horticultural and/or agricultural plant growth. Included in that the soil that does not support the growth of horticultural and/or agricultural plants is contacted with an effective amount of a composition, such as an energy-treated composition as disclosed herein, wherein the composition comprises at least one nourishing element, wherein The at least one nourishing element possesses a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the composition being effective for the soil that does not support horticultural and/or agricultural plant growth (when When an effective amount of the composition is combined, it is converted into a soil capable of supporting the growth of horticultural and/or agricultural plants. The phrase "horticultural plant growth" as used herein refers to plant propagation and cultivation and crop production on a small scale (such as planting in a garden), including, for example, fruits such as berries, nuts, vegetables, flowers, trees, shrubs, and turf. (such as pasture). The phrase "agricultural plant growth" as used herein refers to large-scale (such as agriculture) plant propagation and cultivation and crop production, including, for example, rice, tobacco, wheat, barley, soybeans, potatoes, corn, beets. Fruits, such as berries, watermelons, tomatoes, beans, cucumbers, nuts; other vegetables, flowers; trees, such as apple trees, orange trees and banana trees; shrubs; and turf, such as pasture. Horticultural and agricultural plant growth can be distinguished from isolated plantages (such as sage brushes and cacti, which can be randomly found in soils that cannot support horticultural and/or agricultural plant growth (eg, desert sand)) .

In some embodiments, a soil (such as desert sand) that is used to treat horticultural and/or agricultural plant growth is disclosed to convert the soil into soil capable of supporting horticultural and/or agricultural plant growth. The method comprises: contacting the soil that does not support horticultural and/or agricultural plant growth with an effective amount of a composition, such as an energy treated composition as disclosed herein, wherein the composition comprises at least one nourishing element, And further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in a pre-existing state, the composition being effective for the soil that does not support horticultural and/or agricultural plant growth (when combined with the effective amount of the composition) When combined, it is converted into a soil that supports the growth of horticultural and/or agricultural plants.

In some embodiments, the disclosed composition possesses an energy spectrum that is more positive than the energy spectrum of the composition in a pre-existing state. Without being bound by theory, the corrected energy spectrum is sufficient (eg, sufficiently correct and retained for a sufficient period of time) to improve soil, plant growth, seed, seed quality, plant and/or plant products (including improved quality of plant products) ). In some embodiments, again, not by theory, the corrected energy spectrum is sufficient for the composition to improve soil (including virgin soil, when combined with the composition) to support plant growth, which is less than the soil Good combination with the composition. In some embodiments, again, not by theory, the corrected energy spectrum is sufficient to allow the composition to be selected from sand/loar sand, heavy clay, clay, sandy clay, sandy clay loam, The silty clay, the silty clay loam and the silt loam soil are converted (when the soil is combined with the composition) selected from the modified soil of sandy loam, loamy clay, clay loam and loam. In some embodiments, again, not by theory, the corrected energy spectrum is sufficient to allow the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated with saline to support plant growth, and The soil is compared when not in combination with the composition. The present disclosure also relates to a composition made by performing energy treatment (e.g., electromagnetic treatment) on a composition in a pre-existing state, wherein the treatment increases the relative energy state value of at least one of the nourishing elements in the composition. (Compared to at least one of the nourishing elements in the composition in the pre-existing state), and/or such that the energy spectrum of the composition is corrected to the composition in a pre-existing state. Without being bound by theory, the increased relative energy state value and/or the corrected energy spectrum is sufficient (eg, sufficiently correct and retained for a sufficient period of time) to improve soil, plant growth, seed, seed quality, plant and/or plant products. (including the quality of plant products).

As discussed in more detail below, "relative energy state value" as used herein refers to a magnetic induction of at least one of the nourishing elements in the sample to be measured, in a standard reference sample (such as described below). The ratio of the magnetic induction strength of the same at least one nourishing element in a standard reference sample found in a commercially available machine. The relative energy state values of the nourishing elements can be measured using, for example, a quantum resonance spectrometer (QRS). As also discussed in further detail below, "energy spectroscopy" as used herein refers to the recording of the intensity and frequency of electromagnetic waves measured on a sample. The energy spectrum can be measured using, for example, a spectral analyzer and/or QRS.

The present disclosure also relates to a method of fabricating a composition as disclosed herein by performing energy treatment. Any energy tool (such as electromagnetic, thermal, acoustic, and mechanical tools) effective to treat a composition in a pre-existing state (such as described immediately above) can be used to sufficiently enhance at least one nourishing element in the composition. a relative energy state value (compared to at least one of the nourishing elements in the composition in the pre-existing state), and/or such that the energy spectrum of the composition is sufficiently more correct than the composition in the pre-existing state, perhaps because The increased relative energy state value and/or the corrected energy spectrum retains a sufficiently efficient period of time. In some embodiments, the composition is made by electromagnetic treatment on at least one of the materials of the composition. For example, electromagnetic treatment can be performed on at least one of the materials of the compositions disclosed herein by applying an electromagnetic field to a space (such as a container) in which the at least one material is placed. For example, the composition to be treated is placed in a space (such as a tunnel or enclosed shielding space, such as a shielded space surrounded by ventilation or a shielded space enclosed in a vacuum state, which is a container or any other enclosure a living structure, such as a completely enclosed room, cellar, barn, or other ancillary building (such as a greenhouse) to contain the energy produced in the space; or in other words, to minimize the energy produced This space leaks out. The AC current may be caused to flow through the processing device to generate an electromagnetic field in the space, or by generating an AC current to flow through the processing device to be in the space (such as the space enclosed by the at least one material) A magnetic field is generated in a further container such as a container to perform the electromagnetic treatment. In some embodiments, the processing device can be in the form of a coil. The coil can be wound around the container containing at least one of the materials to be processed, which is shown graphically in FIG. Or the coil may be wound around an object (such as a support or carrier) that does not contain at least one material to be processed in the space to generate electromagnetic energy in the space and to process at least one material in the space, even if The material is not located within the object (ie, the material is located in a space remote from the object). And the machine that produces the electromagnetic field can be inside or outside the enclosed space. In Fig. 11, the broken line represents the magnetic field lines of the electromagnetic field generated by the AC current flowing through the coil (as provided by the AC current generator). The electric field lines are not depicted. In some other specific examples, the processing device can be placed in the form of an antenna in a space in which the material is placed, such as a enclosed space, such as a container. The antenna can also be inserted into at least one of the materials in the space, such as the enclosed space. In some embodiments, the electromagnetic treatment can be performed on the at least one material for a sufficient period of time to obtain a composition as disclosed herein.

In some embodiments, after obtaining a composition as disclosed herein by energy treatment (eg, electromagnetic treatment), routine experimentation can be used to determine the appropriate mixing ratio of the composition to the target soil, for example, By measuring the relative energy state values of at least one of the nourishing elements to see if a suitable relative energy state value is obtained in the mixture, it is therefore observed whether the mixture of the composition and the target soil (ie, the treated soil) is used for improvement. A good candidate for the quality of plant growth, seeds and/or plant products. In certain embodiments, if the treated soil is a good candidate, the compositions disclosed herein can be applied to a larger area of the target soil. Of course, if the composition as disclosed herein is used to improve soil, plant, plant growth, seed, seed quality and/or plant products (including improved quality of plant products), is the improvement actually obtained and increased? It is irrelevant that the relative energy state values or the energy spectra of the positive energy are related in a causal relationship. Of course, the energy treatments disclosed herein can be used on conventional fertilizers (including synthetic and organic fertilizers and mixtures thereof, and biological fertilizers (substances containing living microorganisms)) to increase the relative weight of at least one of the nourishing elements in the fertilizer. The energy state value and/or the energy spectrum that provides the fertilizer correction to achieve at least one of the objectives disclosed herein, such as improving the ability of the soil to support horticultural and/or agricultural plant growth. An additional advantage of the energy treatment of this fertilizer may be that a smaller amount of fertilizer can be used, thereby reducing environmental problems.

The present disclosure also relates to a method for treating soil comprising contacting the soil with an effective amount of the composition disclosed herein. The present disclosure also relates to a method for treating a plant comprising contacting the plant with an effective amount of the composition disclosed herein for a time sufficient to improve the quality of the plant growth, seed and/or plant product.

The present disclosure also relates to an improved soil comprising at least one nourishing element, and to an improved soil treated with an effective amount of at least one of the compositions disclosed herein. The present disclosure also relates to improved plants produced by growing plants in at least one of the improved soils disclosed herein, and from at least one of the compositions disclosed herein and/or otherwise by the disclosure herein Improved seed, seed quality, plant and/or improved plant product (including improved quality of the plant product) produced by plants grown in the modified soil. The present disclosure also relates to a method for making improved soil, improved plants, and improved seeds and/or improved plant products. The present disclosure further relates to a method for use in the compositions disclosed herein; and to a method for treating soil comprising contacting the soil with an effective amount of the compositions disclosed herein; and The disclosed compositions are used to treat plants to produce improved plants, seeds, and/or improved plant products.

In certain embodiments, when the composition disclosed herein and the soil are at a ratio of, for example, 1:1 (by weight) or at any other ratio (which can be evaluated to determine whether it is effective, such as 1:5,000 to 1:1, further such as, for example, 1:2,500, 1:1,000, 1:800, 1:500, 1:250, 1:100, 1:90, 1:80, 1:70, 1:60, 1: 50, 1:40, 1:30, 1:20, 1:10 or 1:1), the composition may increase the relative energy state value (such as at least 10%) of the at least one nourishing element in the soil. Further further such as at least 20%, and even further at least 30%, and even further at least 40%, and even further at least 50%, in a pre-existing state in soil not combined with the compositions disclosed herein Comparison of the relative energy state values of the same nourishing elements) to improve the ability of the soil to be irrigated by saline to support plant growth, and/or to support plant growth better than when the soil is not bound to the composition. As a further embodiment, the amount of the sufficiently increased relative energy state value of the at least one nourishing element may also be, for example, at least 60%, and further, for example, at least 100%, and even further embodiments are at least 200%, and even further Relative energy of at least 400%, and even further further at least 500%, and even further at least 600%, with the same nourishing elements in a pre-existing state in the soil not combined with the compositions disclosed herein Status value comparison.

In certain embodiments, when the composition disclosed herein and the soil are at a ratio of, for example, 1:1 (by weight) or at any other ratio (which can be evaluated to determine whether it is effective, such as 1:5,000 to 1:1, further such as, for example, 1:2,500, 1:1,000, 1:800, 1:500, 1:250, 1:100, 1:90, 1:80, 1:70, 1:60, 1: 50, 1:40, 1:30, 1:20, 1:10 or 1:1) when combined, the composition can reduce the relative energy state value of at least one harmful element in the soil (such as at least 2%) Further, such as at least 5%, even further such as at least 10% and even further at least 15%, compared to the relative energy state values of the same hazardous elements in a pre-existing state in the soil not combined with the compositions disclosed herein ) to improve the ability of the soil to be irrigated by saline to support plant growth, and/or to support plant growth better than when the soil is not combined with the composition. For further embodiments, the amount of the relative energy state value of the at least one harmful element that is sufficiently reduced may also be, for example, at least 20%, and further, for example, at least 50% and even further at least 100%, and There is no comparison of relative energy state values for the same hazardous elements in the pre-existing state in the soil combined with the compositions disclosed herein. In fact, the relative energy state value of the at least one harmful element can even be reduced to zero.

In certain embodiments, a composition as disclosed herein comprises at least one chemical tool for absorbing a sufficient amount of energy (eg, electromagnetic energy) and sufficient time to allow the composition to improve soil (including virgin soil, When combined with the composition) to support plant growth (which is better than when the soil is not combined with the composition). In some embodiments, the absorbed electromagnetic energy is sufficient to allow the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated with saline to support plant growth, and the soil does not Compare when combining materials. In some embodiments, the absorbed electromagnetic energy is sufficient to allow the composition (when combined with soil) to directly or preferably improve the quality of plant growth, seeds, and/or plant products when used to treat plants.

As used herein, "at least one nourishing element" can be any element useful for supporting plant growth and/or improving the quality of plant growth, seeds, and/or plant products. For example, the at least one nourishing element may be selected from the group consisting of nitrogen (N), phosphorus (P), potassium (K), calcium (Ca), magnesium (Mg), and sulfur (S), copper (Cu), iron (Fe). ), manganese (Mn), zinc (Zn), boron (B), molybdenum (Mo) and selenium (Se). As a further embodiment, the at least one nourishing element can be selected from the group consisting of N, P, and K.

For example, the total amount of N, P, and K that may be present is equal to or greater than 0.5% by weight (relative to the total weight of the composition), such as, for example, up to 6% by weight, further such as up to 10% by weight, such as further up to 15% by weight Or even such as further up to 20% by weight (relative to the total weight of the composition). For further embodiments, each of N, P, and K may be present in an amount equal to or greater than 0.1% by weight (relative to the total weight of the composition), such as, for example, up to 2% by weight, such as up to 5% by weight, further such as highest 8 wt%, or even such as up to 10 wt% (relative to the total weight of the composition). As for even further embodiments, the total amount of N, P and K may be equal to or greater than 3% by weight (relative to the total weight of the composition), such as, for example, up to 5% by weight, further such as up to 25% by weight, even further such as Up to 30% by weight, or even further up to 35% by weight (relative to the total weight of the composition). As for even further embodiments, each of N, P and K may be present in an amount equal to or greater than 0.1% by weight (relative to the total weight of the composition), such as, for example, up to 1% by weight, further such as up to 12% by weight, up to Further 15% by weight, or even further up to 20% by weight (relative to the total weight of the composition).

"At least one photosensitive material" as used herein may be an energy spectrum that is capable of absorbing at least one photon, as disclosed herein, at least for a period of time useful, and that is excited to a higher energy state and/or more Maintain any substance for a sufficient period of time. The "at least one photosensitive material" also includes any precursor that can be converted to absorb at least one photon as disclosed herein for at least a sufficiently useful period of time, and to be excited to a higher energy state and/or a more positive energy. A substance that spectra and maintains for a sufficient period of time. For example, the at least one photosensitive material can absorb light having a wavelength of from 350 to 800 nm. As another embodiment, the at least one photosensitive material can absorb light having a wavelength of from 350 to 500 nm. As a further embodiment, the at least one photosensitive material can absorb light having a wavelength of 650-800 nm. As for even further embodiments, the at least one photosensitive material can absorb light having a wavelength of from 500 to 650 nm.

A typical example of the at least one photosensitive material comprises a photosensitive precursor 5-ALA, which is commercially available, for example, from Beijing Yushenghong Chemical Company, Ltd.; rotary screen photosensitizer (rotary screen) Photoensitizer), commercially available from Keqiao Photosensitive Material Factory in Shaoxing, China; photosensitizer 184, available from Dafeng Xinyuanda Chemical Co., Ltd., Jiangsu Province, China (Dafeng) Xinyuanda Chemical Company, Ltd.) is commercially available; RGALA photosensitizer, commercially available from Future Chemical Company, Ltd.; and photosensitizer 1173, which is available from Dafeng Xinyuan Chemical Co., Ltd. Commercially available. As another exemplary embodiment, the at least one photosensitive material may be an extract from a plant. The plant-derived extract may, for example, be an extract from the stamens. The extract can be of industrial grade.

Although specific embodiments of the experiments conducted and reported herein use a combination of 5-ALA and other identified materials to achieve at least one of the surprising and unpredictable results disclosed herein, those skilled in the art can Routine experiments conducted by the guidance of this patent specification to identify other photosensitive materials as defined herein, which may be used alone as the at least one photosensitive material or in combination with other materials to achieve at least one of the texts herein. The results revealed.

Those skilled in the art will also be aware of other suitable materials (eg, photosensitive materials, organic acids, and organic base materials containing at least one hazardous element such as Cl, Al, lead, mercury, arsenic, cadmium, and chromium). There are side effects on the soil treated therewith, and thus may not be suitable for use in the methods, compositions, and other specific examples disclosed herein.

The at least one photosensitive material may be any substance comprising at least one unsaturated bond, such as at least one conjugated double bond, which is not deleterious to the soil and/or plant to be treated. As an example, the at least one photosensitive material may comprise at least one substituted or unsubstituted aromatic component, for example, at least one carbocyclic aryl and/or heteroaryl component (substituted or unsubstituted) .

"Carbocyclic aryl" as used herein includes: a 6-membered carbocyclic aromatic ring, for example, benzene; a bicyclic ring system in which at least one ring is carbocyclic and aromatic, for example, naphthalene, hydroquinone, and tetralin And a three-ring ring system in which at least one ring is carbocyclic and aromatic, for example, ruthenium. The carbocyclic aryl group may be substituted or unsubstituted.

"Heteroaryl" includes: a 5 to 7 membered aromatic monocyclic ring comprising one or more (eg, from 1 to 4, or in some embodiments, from 1 to 3) selected from N, O. And a ring heteroatom of S and the remaining ring atomic carbon; a bicyclic heterocycloalkyl ring comprising one or more (eg, from 1 to 4, or in some embodiments, from 1 to 3) From the ring heteroatoms of N, O and S and the remaining ring atomic carbon, and at least one of the heteroatoms thereof, are present in the aromatic ring; and the tricyclic heterocycloalkyl ring, which comprises one or more (eg , from 1 to 5, or in some embodiments, from 1 to 4) a ring hetero atom selected from N, O and S and a remaining ring atomic carbon, and at least one of the hetero atom systems is present in the aromatic ring . The heteroaryl group can be substituted or unsubstituted.

For example, the heteroaryl group includes a 5- to 7-membered heterocycloalkyl group, and is bonded to an aromatic ring of a 5- to 7-membered cycloalkyl or heterocycloalkyl ring. For this combined bicyclic heteroaryl ring system, wherein only one of the rings contains one or more heteroatoms, the attachment point can be at either ring. Examples of such heteroaryl groups include, but are not limited to, (e.g., counting from a linkage position designated by priority 1) 2-pyridyl, 3-pyridyl, 4-pyridyl, 2,3-pyridyl Base, 3,4-pyridyl Base, 2,4-pyrimidinyl, 3,5-pyrimidinyl, 2,3-pyrazolyl, 2,4-imidazolinyl, iso Oxazolinyl, Oxazolinyl, thiazolinyl, thiadiazolinyl, tetrazolyl, thienyl, benzothienyl, furyl, benzofuranyl, benzimidazolyl, porphyrin, anthracene Base, triazolyl, quinolyl, pyrazolyl and 5,6,7,8-tetrahydroisoquinolinyl. Other examples of such heteroaryl groups include, but are not limited to, isoquinolinyl, iso Zylo-3-yl and iso Azole-5-yl.

As a further embodiment, the at least one photosensitive material may be selected from the group consisting of alkyl spiropyrans, trienes, dienes, and azo compounds. The azo compound may comprise any compound bearing a functional group R-N=N-R', wherein R and R' may each independently be selected from the group consisting of H, aryl, heteroaryl, alkyl, alkenyl and alkynyl. For example, the azo compound may include HN=NH, diphenyldiazide, and/or diethyldiazenene.

"Alkyl" as used herein, includes both substituted and unsubstituted, straight and branched chain saturated hydrocarbons having the specified number of carbon atoms, typically from 1 to 20 carbon atoms, for example from 1 to 8 carbon atoms. , such as 1 to 6 carbon atoms. For example, a C1-C6 alkyl group includes both straight and branched alkyl groups having from 1 to 6 carbon atoms.

"Alkenyl" as used herein includes both substituted and unsubstituted, branched and straight chain hydrocarbon groups having at least one carbon-carbon double bond. This group can be configured in cis or trans for this double bond. Typical alkenyl groups include, but are not limited to, vinyl; propenyl species such as prop-1-en-1-yl, prop-1-en-2-yl, prop-2-en-1-yl (allyl , propyl-2-en-2-yl; butenyl, such as but-1-en-1-yl, but-1-en-2-yl, 2-methyl-prop-1-ene 1-yl,but-2-en-1-yl,but-2-en-1-yl,but-2-en-2-yl,butyl-1,3-dien-1-yl and butyl-1 , 3-dien-2-yl.

"Alkynyl", as used herein, includes both substituted and unsubstituted, branched and straight-chain hydrocarbon groups having at least one carbon-carbon triple bond. Typical alkynyl groups include, but are not limited to, ethynyl; propynyl, such as prop-1-yn-1-yl, prop-2-yn-1-yl; and butynyl, such as but-1- Alkyn-1-yl, but-1-yn-3-yl, but-3-yn-1-yl.

As for even further embodiments, the at least one photosensitive material can be a terpene. The terpenes can be synthetically prepared or extracted from plant sources. Examples of the terpenes include, but are not limited to, citronellol, decene, terpineol, bacteriocin, bacteriocin, retinol, retinal, phytol, coffee oleyl alcohol, Coffee white fat (kahweol), cembrene, taxadiene, geranyl green alkenyl alcohol and squalene.

The at least one photosensitive material can be present in the composition, for example, in an amount of up to about 15%, such as in the range of from about 0.00001% to about 10%, from about 0.0001% to about 5%, from about 0.001% to about 3.5%, and about From 0.01% to about 2.5% by weight (relative to the total weight of the composition). In some embodiments, the amount of the at least one photosensitive material can be more conveniently disclosed in units of parts per million ("ppm") relative to the total weight of the composition. Thus, as a further embodiment, the at least one photosensitive material can be present in the compositions disclosed herein in a range from about 0.1 ppm to about 100 ppm, such as from about 0.5 ppm to about 10 ppm, from about 1 ppm to about 5 ppm, from about 1.5 ppm to about 2 ppm (based on the weight of the total weight of the composition). In another embodiment, the at least one photosensitive material can be present in the composition in a range from about 0.15 ppm to about 0.4 ppm by weight relative to the total weight of the composition. As a further embodiment, the at least one photosensitive material can be present in the composition in a range from about 0.2 ppm to about 0.3 ppm by weight relative to the total weight of the composition.

"At least one organic acid" as used herein may be any organic material that at least partially supplies hydrogen ions (protons) and/or complex hydrogen ions (widely, such as R‧.H ⁺ , wherein R is an organic base such as NH ₄ ⁺ or NH ₃ C ₂ H ₅ ⁺ ). For example, the at least one organic acid may comprise at least one functional group selected from the group consisting of a carboxylic acid group, a sulfonic acid group, an enol group, a phenol group, and a thiol group, and chemically modified in a well-known manner (such as in These functional groups are esterified in the case of a carboxylic acid group. As another embodiment, the at least one organic acid may be selected from the group consisting of humic acids and alginic acids (also known as alginic acid or alginate). As a further embodiment, the at least one organic acid species can be selected from the group consisting of nucleic acids, amino acids, and fatty acids. The amino acid can be selected from the group consisting of amino acids which are beneficial to the quality of plant growth, seeds and/or plant products. For example, the amino acid can be an agricultural grade amino acid, for example, an amino acid mixture commonly used for agricultural purposes. For example, an agricultural grade amino acid comprising 47% to 51% of a mixture of 17 amino acids commercially available from Penghengbo Biochemical Company of Nanhe County, Hebei Province, China. As a further example, the amino acid can be selected from certain 20 naturally occurring amino acids and synthetically modified amino acids. As for even further embodiments, the amino acid can be included in the hydrolyzed protein (ie, a mixture of amino acids and/or peptides), for example, hydrolyzed proteins from soy proteins. The nucleic acid can be any nucleic acid additive suitable for fertilizer or plant nutrients. The fatty acid can be any linear or branched fatty acid. For example, the fatty acid can comprise at least one chain comprising from 4 to 28 carbons. As another example, the fatty acid may comprise at least one chain of 4 to 18 carbons, such as 8 to 16 carbons. The at least one chain can be saturated or unsaturated. As another example, the fatty acid may be selected from the group consisting of caproic acid, heptanoic acid, caprylic acid, capric acid, capric acid, undecanoic acid, dodecanoic acid, tridecanoic acid, tetradecanoic acid, pentadecanoic acid, and hexadecanoic acid. Heptadecanoic acid, stearic acid (octadecanoic acid), lauric acid, icosonic acid, myristic acid, palmitoleic acid, sapinic acid, oleic acid, linoleic acid, α-Asia Oleic acid, α-limenic acid, arachidonic acid, and decyl pentenoic acid.

Although the specific embodiments in this disclosure are based on the experiments conducted and reported herein, the use of stearic acid and/or agricultural grade amino acids in combination with other identified materials achieves at least one of the amazing aspects disclosed herein. Unpredicted results, those skilled in the art can be explored by routine experimentation guided by this patent specification to identify other organic acids as defined herein (which can be used alone as the at least one organic acid) Or in combination with other materials to achieve at least one of the results disclosed herein).

The at least one organic acidic material may be present in the composition, for example, in the range of from about 0.1% to about 25% by weight (relative to the total weight of the composition). For example, the at least one organic acidic material can range from about 0.1% to about 5%, from 0.5% to about 4%, from 1% to about 3%, from about 1% to about 10%, from about 2% to about 9%, from about 3 % to about 8%, about 4% to about 7%, about 5% to about 6%, about 8% to about 25%, about 10% to about 22%, about 12% to about 20%, about 15% to An amount of about 18% by weight (relative to the total weight of the composition) is present.

"At least one organic base material" as used herein may be any organic material that provides carbon. The at least one organic base material can be fermented or unfermented. The at least one organic base material may be selected from organic residues from the food, beverage, and chemical industries, such as substituted and unsubstituted furans, and granules of distillers; and from the manufacture of monosodium glutamate and / or residue of the process of flavor flavor. For example, the at least one organic base can be obtained from any plant (such as crops and pastures) or any part of the plant (such as bark, roots and leaves). In another embodiment, the at least one organic base material may be selected from the group consisting of stalk powder, wood shavings, sawdust, and Chinese herbal medicine dregs. As a further embodiment, the at least one organic base material can be from garden trims (such as grass and shrub trim), leaves, hay, stalks, chopped bark, whole bark nuggets, sawdust, outer shell, Wood chips, waste paper (such as chopped newspapers and cardboard), animal manure, compost, kitchen waste, whole trees, branches or twigs, and/or tree residues are obtained. In at least some embodiments, the organic base material is different from the photosensitive material and/or organic acid.

The at least one organic base material may be present in the composition in a range from about 60% to about 90% by weight (relative to the total weight of the composition). For example, the at least one organic base material can be present in an amount ranging from about 65% to about 85%, from about 65% to about 75%, or from about 70% to about 80% by weight, relative to the total weight of the composition.

In certain embodiments, the compositions disclosed herein can comprise, for example, from about 0.0001% to about 5% by weight of at least one photosensitive material, from about 10% to about 20% by weight of at least one organic acid, and about 75%. Up to about 90% by weight of at least one organic base material (relative to the total weight of the composition).

By way of example, for the compositions disclosed herein, the first composition can be present in a range from about 5% to about 20% by weight relative to the total weight of the composition. The second composition can be present in a range from about 5% to about 20% by weight relative to the total weight of the composition. The third composition can be present in a range from about 60% to about 90% by weight relative to the total weight of the composition.

For a plurality of compositions disclosed herein, in addition to the at least one organic acidic material, the first composition may further comprise at least one selected from the group consisting of photosensitive materials, organic basic materials, inorganic materials, and more. Sugars, water absorbing agents, proteins, non-protein enzymes and traditional chemical fertilizers. In addition to the at least one photosensitive material, the second composition may further comprise at least one selected from the group consisting of organic acidic substances, organic basic substances, colloids, inorganic substances, polysaccharides, and water absorbing agents.

"Colloid" as used herein may be selected from the group consisting of organic, inorganic and organic-inorganic composite colloids. For example, the colloid can be formed from pectin, which is a heteropolysaccharide. For further embodiments, the colloid may be selected from the group consisting of agar, carrageenan, and gelatin.

"Inorganic" as used herein includes any suitable form of inorganic material, and may be selected from inorganic salts and inorganic complexes selected from the group consisting of citrates, carbonates, sulfates, oxides, phosphoric acids. Salts, oxalates, melitates, citrates, acetates, formates and hydrocarbons. For example, the inorganic material may be selected from the group consisting of manganese sulfate, zinc sulfate, copper sulfate, ferrous sulfate, ammonium molybdate, and borax (ie, sodium borate). The inorganic material may be in any form of rock suitable for improving the quality of soil, plant growth, seeds and/or plant products. For example, the inorganic material may be selected from the group consisting of phosphate rock, potassium rock, shell rock, and zeolite. As a further embodiment, the inorganic material may be selected from the group consisting of bone meal (such as fish bone meal), lime, and icy rock powder. The inorganic material can be ground to particles of suitable size suitable for improving the quality of the soil, plant growth seeds and/or plant products. For example, the inorganic material can be broken into particles having a size of no greater than about 5 mm. As another embodiment, the inorganic material can be broken into particles having a size of no more than about 3 mm. Particle "size" as used herein means that the particle can pass through a sieve having a mesh size of its size.

The inorganic material may be present in the composition, for example, in an amount of from about 0.1% to about 10%, for example, from about 0.5% to about 8%, from about 0.8% to about 5%, from about 1% to about 4%, from about 1% to about 3% and from about 1% to about 2% by weight relative to the total weight of the composition.

A "polysaccharide" as used herein may be selected from polymeric carbohydrates. For example, the polysaccharide may be selected from the group consisting of starch, glycogen, cellulose, and chitin. The starch can be obtained, for example, from any plant. In some embodiments, the starch is available from foods such as beans, potatoes, wheat, corn, and rice. As further examples, the polysaccharide may be selected from the group consisting of peptidoglycans, lipopolysaccharides, capsules, extracellular polysaccharides, dextran, agarose, hyaluronic acid, dermatan sulfate, keratan sulfate (keratan). Sulfate, chondrotin sulfate, heparin and proteoglycan. Certain polysaccharides can form colloids, and the term "polysaccharide" also includes oligosaccharides.

The polysaccharide may be present in an amount of, for example, from about 0.1% to about 10%, for example, from about 0.5% to about 8%, from about 0.8% to about 5%, from about 1% to about 4%, from about 1% to about 3%. And from about 1% to about 2% by weight relative to the total weight of the composition.

A "water absorbing agent" as used herein may be selected from any substance that can absorb and/or retain water. For example, the water absorbing agent may be selected from water absorbing gels and water absorbing polymers (such as APP, commercially available from Beijing Gaojing Resin Company). As a further embodiment, the water absorbing agent may be selected from the group consisting of crosslinked polymers (for example, polyethylene oxide and polyvinylpyrrolidone), polyoxyhydrogels, and polypropylene amides. gel. Of course, any other material in the compositions disclosed herein may also have certain water absorption properties. For example, pectin, which can be a colloid, can also act as a water absorbing agent.

The water absorbing agent may be present in the composition in an amount of, for example, less than or equal to about 10% by weight (relative to the total weight of the composition), for example, less than or equal to about 7%, as for further embodiments, less than or equal to About 5%, such as, for example, less than or equal to about 4%, such as less than or equal to about 3%, and such as even further less than or equal to about 2%, and further less than or equal to about 1%.

A "non-proteinaceous enzyme" as used herein may be selected from a coenzyme. The coenzyme can be selected from the group consisting of vitamins and non-vitamin coenzymes. For example, the coenzyme may be selected from the group consisting of thiamine, biotin, folic acid, coenzyme A, ascorbic acid, riboflavin, coenzyme B, and coenzyme Q.

By way of example, for the compositions disclosed herein, the first composition can comprise, for example, from about 50 to 80% by weight of stalk powder, from about 8 to 20% by weight of phosphate ore granules, from about 5 to 20% by weight. Agricultural grade amino acid, less than or equal to about 7% by weight fatty acid (such as stearic acid), about 3-10% by weight starch (such as corn or potato starch), less than or equal to about 5% by weight of water absorbing agent , about less than or equal to 2% by weight of manganese sulfate, about less than or equal to 2% by weight of zinc sulfate, about less than or equal to 1.5% by weight of copper sulfate, about less than or equal to 4% by weight of ferrous sulfate, About less than or equal to about 1% by weight ammonium molybdate, and less than or equal to about 1.2% by weight borax (relative to the total weight of the first composition). As used herein, the phosphate ore granules are commercially available and are commercially available, for example, from Yi Chang Fu Lin Chemicals (Group) Co. Ltd., Hubei Province, China. .

The second composition may, for example, comprise from about 50 to 80% by weight of stalk powder, from about 8 to 20% by weight of phosphate ore granules, from about 5 to 20% by weight of agricultural grade amino acid, less than or equal to about 7 weight % fatty acid, about 3-10% by weight starch (such as corn or potato starch), less than or equal to about 7% by weight of water absorbing agent, about less than or equal to 2% by weight of manganese sulfate, less than or equal to 2 weight % zinc sulfate, less than or equal to 1.5% by weight copper sulfate, less than or equal to 4% by weight ferrous sulfate, less than or equal to about 1% by weight ammonium molybdate, and less than or equal to about 1.2. % by weight of borax (relative to the total weight of the second composition), and further comprising about 1-3 ppm by weight of 5-ALA (relative to the total weight of the second composition).

In certain embodiments, the compositions disclosed herein can comprise about 10% by weight of the first composition, about 20% by weight of the second composition, and about 70% by weight of the third composition, as opposed to The total weight of the composition. For the purpose of clarity, those compositions are indicated as "Composition A." Composition A (such as that already energy treated) as disclosed herein may be suitable for treating various types of soil (eg, salt and/or alkaline soil) to make it more suitable for plant growth.

In certain embodiments, the compositions disclosed herein can comprise about 15% by weight of the first composition, about 15% by weight of the second composition, and about 705% by weight of the third composition, as opposed to The total weight of the composition. Those compositions are indicated as "Composition B" for the sake of clarity. Composition B (such as that already energy treated) as disclosed herein may be suitable for treating various types of soil (eg, dry soil, such as desert sand soil) to make it more suitable for plant growth.

In certain embodiments, the composition A and the composition B as disclosed herein can be combined, for example, in a ratio of 1:1 (by weight) (eg, wherein one or both of the compositions A and B are Energy treatment) to form another composition, which is indicated as "Composition C." In certain embodiments, depending on the starting material and as long as the composition C is suitable to achieve at least one of the results disclosed herein, the composition A and composition B can be from 0.01:1 to 1:0.1 by weight. The ratio ranges are combined, such as, for example, 0.1:1, 0.25:1, 0.5:1, 0.75:1, 1:1, 1:0.75, 1:0.50, or 1:0.25. The composition C can be adapted to treat a variety of types of soil (eg, dry, salt, and/or alkaline soils) to make it more suitable for plant growth.

For the compositions disclosed herein, the first, second, and third compositions may or may not be in contact with one another. For example, the first composition, the second composition, and the third composition can be stored in separate locations, such as in three different containers, for example, avoiding light, without physical contact with each other. As another embodiment, the first composition, the second composition, and the third composition are separately packaged and then mixed together to form a mixture before contacting the soil and/or the plant. As a further embodiment, at least two of the first, second and third compositions are combined. As for even further embodiments, the first composition and the second composition and the package are mixed together while the third composition is separately packaged. This third composition can then be added to the mixture of the first and second compositions to form another mixture. As for even further embodiments, the first, second and third compositions are not combined, even when they are placed in contact with soil and/or plants. For example, the first composition can be sprayed or spread on the leaves of the plant, the second composition can be sprayed or spread on the stem of the plant, and the third composition can be associated with the roots of the plant and/or Or contact with the soil in which the plant grows. Further, each of the first, second, and third compositions may be applied to the soil to be treated.

The compositions disclosed herein can be solid, liquid or semi-liquid. For example, the composition can be in the form of a slurry. As another embodiment, at least one of the first and second compositions may be in liquid form. When the compositions disclosed herein are solids, the solids may be in powder form. When the composition disclosed herein is applied to soil and/or plants, the composition can be combined with at least one material selected from the group consisting of seeds and soils in different shapes and forms. For example, the composition can be mixed with seeds and/or soil and wrapped in a suitable water permeable material, such as a straw bag, and then implanted into a target soil such as a virgin soil. The composition disclosed herein may also form a brick (which includes seeds and/or soil in addition to the composition) which may then be implanted into the target soil. The composition can also be used with soil and/or seeds to form pellets, and can be applied to the soil in a variety of ways, such as using a plane to dust a crop.

The compositions disclosed herein may comprise particles. For example, the particles can have a size no greater than about 5 millimeters. As another example, the particles can have a size no greater than about 3 millimeters. As mentioned above, the "size" of a particle as used herein means that the particle can pass through a sieve having a mesh size of its size.

The present disclosure also relates to a composition comprising at least one nourishing element (referred to herein as a "water soluble composition") wherein the amount of any water insoluble material in the composition is at room temperature and atmospheric pressure. Not more than about 5% by weight (relative to the total weight of the composition). For example, the amount of insoluble material in the composition may not exceed about 2% by weight (relative to the total weight of the composition) at room temperature and atmospheric pressure. The "water-soluble composition" may be a composition in which at least 95% by weight of the composition is dissolved in water at room temperature and atmospheric pressure. In certain embodiments, at least one of the nourishing elements in the water-soluble composition as disclosed herein has a relative energy state value greater than at least one of the nourishing elements in the pre-existing state of those compositions. . Not limited by theory, a large relative energy state value is sufficient (eg, sufficient value and retained for a sufficient period of time) to improve soil, plant, plant growth, seed, seed quality, and/or plant products (including improvements in plant products) Quality). In certain embodiments, not limited by theory, a larger relative energy state value is sufficient for the water soluble composition to improve soil (including virgin soil when combined with the water soluble composition) Plant growth is supported which is better than when the soil is not combined with the water soluble composition. In some embodiments, again, not limited by theory, a larger relative energy state value is sufficient for the water soluble composition to be selected from sand/loar sand, heavy clay, clay, sand. The soil of clay, sandy clay loam, silty clay, silty clay loam and silt loam is converted into modified soil selected from sandy loam, loamy clay, clay loam and loam, when the soil is When the water-soluble composition is combined. In some embodiments, again, not by theory, a larger relative energy state value is sufficient for the water soluble composition to improve the soil (when combined with the water soluble composition) from brine The ability to irrigate to support plant growth is compared to when the soil is not combined with the water soluble composition.

In some embodiments, the disclosed water soluble composition possesses an energy spectrum that is more accurate than the energy spectrum of the water soluble composition in a pre-existing state. Without being bound by theory, the corrected energy spectrum is sufficient (eg, positive enough and retained for a sufficient period of time) to improve soil, plant growth, seed, seed quality, plant and/or plant products (including improved quality of plant products) ). In some embodiments, again, not by theory, the corrected energy spectrum is sufficient for the water-soluble composition to improve soil (including virgin soil when combined with the water-soluble composition) Plant growth is supported which is better than when the soil is not combined with the water soluble composition. In some embodiments, again, not by theory, the corrected energy spectrum is sufficient for the water soluble composition to be selected from sand/loar sand, heavy clay, clay, sandy clay, The soil of sandy clay loam, silty clay, silty clay loam and silt loam is converted into modified soil selected from sandy loam, loamy clay, clay loam and loam (when the soil and the soil are When the water-soluble composition is combined). In some embodiments, again, not by theory, the corrected energy spectrum is sufficient for the water-soluble composition to improve soil (when combined with the water-soluble composition) to be irrigated with brine The ability to support plant growth is compared to when the soil is not combined with the water soluble composition.

For example, as seen in Figure 7B, the area under the curve of the energy-treated composition, or the energy-treated water-soluble composition, or the soil combined with the energy-treated composition may have more a total positive area under a curve of 10% (relative to the total positive area under the curve of the composition that is not so treated, or the water-soluble composition that is not so treated, or the soil that is not so combined), such as more than 20 %, such as more than 30%, such as more than 40%, such as more than 50%, such as more than 60%, such as more than 70%, such as more than 80%, such as more than 90% and such as more than 100%.

For example, the water-soluble composition can comprise ingredients that provide primary nourishing elements such as N, P, and K. As another example, the water-soluble composition may comprise a component that provides a trace amount of nourishing elements such as Zn, Cu, and Fe. As a further embodiment, the water-soluble composition may comprise humic acid. As for even further embodiments, the water soluble composition may comprise an amino acid. As for even further embodiments, the water soluble composition can comprise an alginate. The water-soluble composition can be made into a solid form or a liquid form. The water-soluble composition in solid form can be applied directly to the soil or any part of the plant, or can be dissolved in water prior to application. The liquid form can be, for example, a solution, a suspension or a slurry. The water-soluble composition in liquid form can be applied directly to the soil or any part of the plant.

The present disclosure also relates to a method of applying a water-soluble composition as disclosed herein, comprising contacting the water-soluble composition with soil or any part of a plant. For example, the water-soluble composition can be applied to soil or plants by conventional methods such as spraying, dripping, irrigating, and/or soaking.

For example, the water-soluble composition may comprise: 50 kg / m ^ 3 - 300 kg / m ^ 3 (for example, 100 kg / m ^ 3 to 300 kg / m ^ 3 , 150 kg / m ^ 3 to Agricultural grade amino acids of 300 kg/m3, 200 kg/m3 to 300 kg/m3 and 220 kg/m3 to 270 kg/m3; 5 kg/m3 to 50 Kilometers per cubic meter (eg 10 kg/m3 to 40 kg/m3 and 10 kg/m3 to 30 kg/m3); 10 kg/m3 to 100 kg/ A cubic meter (for example, 20 kg/m3 to 80 kg/m3, 30 kg/m3 to 70 kg/m3 and 40 kg/m3 to 60 kg/m3) Zinc; 5 kg / m ^ 3 to 80 kg / m ^ 3 (for example, 10 kg / m ^ 3 to 70 kg / m ^ 3 , 10 kg / m ^ 3 to 50 kg / m ^ 3 and 20 kg / cubic Manganese sulphate up to 40 kg/m3; 5 kg/m3 to 50 kg/m3 (eg 10 kg/m3 to 40 kg) Boric acid per cubic meter and 10 kg/m3 to 30 kg/m3; 5 kg/m3 to 50 kg/m3 (eg 10 kg/m3 to 40 kg/m3) Potassium sulfate with a ruler and 10 kg/m3 to 30 kg/m3; and 0.5 g/m3 to 10 g/m3 (for example, 0.5 g/m3 to 8 g/m3) 5-ALA from 1 gram per cubic meter to 6 grams per cubic meter, from 1.5 grams per cubic meter to 5 grams per cubic meter and from 1.5 grams per cubic meter to 3 grams per cubic meter, all Relative to the weight of the total volume of the composition.

Those ingredients are commercially available from Shunyi Agrcultural Materials Company, Beijing, China.

In one embodiment, the water-soluble aqueous composition comprises: an agricultural grade amino acid of about 250 kg/m3, copper sulfate of about 20 kg/m3, and about 50 kg/m3. Zinc sulphate, about 30 kg/m^ of manganese sulphate, about 20 kg/m3 of boric acid, about 20 kg/m3 of potassium sulphate, and about 2 g/m3 of 5-ALA, all The remainder was added to 100% with water relative to the weight of the total volume of the composition.

As mentioned above, the inventors have discovered novel compositions for practical use and methods of making and using the compositions, such as, in certain embodiments, for improving soil, plant growth, seeds and/or plant products. The quality is achieved in at least one of the results as disclosed herein. The inventors have also discovered an improved soil comprising improved soil prepared by the method disclosed herein; a modified plant, a modified plant made by the method disclosed herein; Seeds (including improved quality of seeds), improved seeds (including improved quality of seeds made by the methods disclosed herein); improved plant products (including improved quality of plant products) And/or improved plant products (including improved qualities of plant products made by the methods disclosed herein).

As used herein, "soil" can be broadly referred to as any solid and/or semi-solid portion of the upper layer of the soil, including soils as generally mentioned, and compositions of soils that are not normally mentioned (such as desert sand). For example, the soil may be soil suitable for plant growth, or soil (such as sand) that is not suitable for plant growth. As another example, the soil may be soil from which plants have been grown. As a further embodiment, the soil may be virgin soil, i.e., soil in which plants have not yet grown, such as, for example, soils that are not suitable for plant growth, such as very alkaline or desert soils. In some embodiments, the virgin soil can be selected from sand, such as desert sand. Some (but not all) soils can be classified into twelve types, such as heavy clay, clay, sandy clay, loamy clay, silty clay, sand, by the International Soil Texture Triangle Classification System as shown in Figure 1. Viscous loam, clay loam, silty clay loam, sand/loamy sand, sandy loam, loam and silt loam.

The soil that can be treated as disclosed herein can be selected from virgin soils such as sand, for example, desert sand. The soil which can be treated as disclosed herein can also be selected from sand/loamy sand, heavy clay, clay, sandy clay, sandy clay loam, silty clay, silty clay loam and silt. Loam. For example, the soil to be treated may be selected from sand/loamy sand, heavy clay, clay, sandy clay, and silty clay. As a further embodiment, the soil to be treated may be selected from sand/loar sand. As for even further embodiments, the soil to be treated may be selected from sand, such as desert sand. Even superior silt loam can be significantly improved by the ability to be used for plant growth and/or irrigation with saline due to at least one of the methods and/or compositions disclosed herein.

As another example, a composition as disclosed herein can reduce the relative energy state values of at least one hazardous entity in the soil when the soil is treated with the compositions disclosed herein. The soil may contain at least one harmful entity that is not beneficial to plant growth. "At least one harmful entity" as used herein may be selected from harmful elements such as Cl, Al, lead, mercury, arsenic, cadmium and chromium; harmful substances such as bacterial toxins, salty substances, alkaline substances and Organisms (such as pests, bacteria and viruses).

In certain embodiments, the modified soil comprises a composition as disclosed herein, or an altered form of the composition as disclosed herein. For example, certain components in the composition may undergo chemical or physical changes before and/or after treatment of the soil with the composition as disclosed herein, such that the composition may be in a chemically or physically altered form (which The composition is present after energy treatment and/or in a form prior to combination with the soil, and it is also possible that the form can be continuously changed after energy treatment and before being combined with the soil, and after initial combination with the soil. The modified soil may comprise at least one nourishing element having sufficient relative energy state values (eg, values and retention for a sufficient period of time) to allow the improved soil to improve plant growth, seed and/or plant product quality. It is better than the soil before treatment. In another embodiment, the modified soil can comprise at least one nourishing element having sufficient relative energy state values (eg, values and retention for a sufficient period of time) to allow the modified soil to be partially or fully utilized Salt water irrigation to improve the quality of plant growth, seeds and / or plant products. As a further embodiment, the modified soil may have a sufficiently corrected energy spectrum and a sufficient amount of time to support plant growth, which is better than the soil before treatment. As for even further embodiments, the modified soil may have a sufficiently positive energy spectrum for a sufficient period of time to support plant growth in part or all by saline irrigation, whereas untreated soil may not be so irrigated.

The soil to be treated and improved according to the present disclosure (sometimes referred to as "the soil to be improved" or "the target soil") may be selected from sand/loamy sand, heavy clay, clay, sandy clay, sandy clay loam. , silty clay, silty clay loam, silt loam, sandy loam, loamy clay, clay loam and loam. For example, the soil to be modified may be selected from sand/loamy sand, heavy clay, clay, sandy clay, sandy clay loam, silty clay, and silty clay loam. For another embodiment, the soil to be modified may be selected from sand/loamy sand, heavy clay, clay, sandy clay, and silty clay. In still another embodiment, the soil to be modified may be sand/loar sand. In still another embodiment, the soil to be modified may be selected from the group consisting of sandy clay loam, silty clay loam, silt loam, sandy loam, loamy clay, clay loam, and loam. In still another embodiment, the soil to be modified may be selected from the group consisting of sandy loam, loamy clay, clay loam, and loam. As a further embodiment, the soil to be modified may be selected from sandy loam and loam. As for even further embodiments, the soil to be modified may be loam.

"Plant" as used herein means any plant, including agricultural and horticultural plants as defined above. The plant may be a grain plant such as wheat, rice, potatoes, beans (such as soybeans), tomatoes, raspberries, vines, pineapples, fruit trees (such as bananas, oranges, apples, and pear trees) and corn. Crops; or plants that can be used by themselves as food (such as for animals), such as hay; or plants that can be used as at least one source of oil, including agricultural or industrial oils, such as sesame oil from sesame, or castor oil plants Or Taiwanese paulownia (jatropha curcas), and further palm oil, such as palm oil, coconut oil, and palm kernel oil, rapeseed oil/canola oil, olive oil from olive tree fruit, corn germ oil from corn Or plants that can be used to make daily necessities, such as cotton trees, fruit trees, and the like. The plant may also be tobacco, wherein the leaves are used to make a product such as a cigarette. The plant may also include plants that are grown rather than used for food manufacturing purposes, for example, trees, shrubs, short groves, flowers, and/or grasses that can be grown, for example, for aesthetic, environmental, or even athletic purposes. As a further embodiment, the plant may include growing grass for use, for example, in a grass or golf course, an international soccer field, or an American football field.

"Plant growth" as used herein includes the growth of agricultural and horticultural plants, as described above. Plant growth can include the growth of any part of the plant, such as roots, leaves, stems, stems, branches, seeds, and/or flowers. Plant growth can be the growth of agricultural plants. For example, plant growth can include increasing the yield of plant products, including, for example, increasing the amount of fruit, nuts, and/or vegetables produced per unit of plant; and/or increasing biomass, for example, the fruits, nuts, of plants of economic value. Leaves, stems, roots and any other part. For another embodiment, the plant growth can improve grain yield, such as quantitatively improving the yield per plant of a variety of grains or vegetables. For another embodiment, the plant growth includes an increase in growth in plant size, plant growth rate, and number of plants grown per acre. As another example, the plant growth includes increasing the yield and/or size of the seed, such as increasing the number of seeds, increasing the weight of the seed, and/or increasing the number of filled seeds. For further embodiments, the plant growth includes increased disease resistance, increased pest resistance, increased drought tolerance, increased low temperature tolerance, and increased stress tolerance. In certain other specific examples, the plant growth line is selected from, for example, the growth of grasses used in grasslands or for golf courses, the growth of trees, or the growth of flowers.

As used herein, "modified plant" refers to a plant that has undergone improved plant growth, and the improved plant also possesses at least one other improved feature, as described immediately above.

"Modified seed" as used herein is meant to produce at least one improved characteristic and/or improved quality as described above (eg, taste, nutrition, germination rate, reproductive time, from planting). Seeds of plants up to the time of collection, increasing the idle life and/or appearance of the seeds. As used herein, "improved seed quality" is a modified seed that is additionally further improved in at least one of the characteristics, such as being stronger, producing higher plant yields, and increasing disease resistance. Increase pest resistance, increase drought tolerance, increase low temperature resistance, increase stability associated with decomposition and/or attenuation, and increase stress tolerance.

"Modified plant product" as used herein refers to being obtained from any part of a plant (eg, fruit, leaves, stems, vegetables, nuts, roots, and/or seeds), for example, in taste, nutrition, size (such as Any product that has increased height, leaf size), structural features (such as improved stem strength), and/or improved quality in appearance. As used herein, "improved quality of a plant product" is an improved plant product that is additionally further improved in at least one characteristic of the plant product, such as texture, taste, color, and nutritional value. Increase disease resistance, increase pest resistance, increase drought tolerance, increase low temperature tolerance, increase stability associated with decomposition and/or attenuation, and increase stress tolerance.

As used herein, "modified soil" refers to soil that has been modified so that the soil can improve the quality of plant growth, seeds, and/or plant products, as compared to unmodified soil; or as further examples Refers to the soil that has been modified so that the growth of the plants therein can be irrigated in whole or in part by saline. For example, at least one of the physical, chemical, and biological characteristics of the soil can be improved in a balanced manner, such as improved soil moisture, improved soil gas permeability, and improved gas content of the soil. For example, the soil can be modified to have a combination of, for example, 3 to 5% gas phase (such as 5%), 45 to 70% solid phase (such as 60%), and 30 to 35% liquid phase (such as 35%). And in some embodiments, when at least one of the physical, chemical, and biological characteristics of the soil is improved in a balanced manner, at least one of those improvements can be maintained for a prolonged period of time (such as 2 to 10 years). And in certain target soils (such as desert sand), it is basically impossible to support plant growth. The soil modified according to the present disclosure may be soil capable of supporting this growth. And in some of the standard soils, if salt water is used to irrigate the plant, it is almost impossible to support plant growth. The soil modified according to the present disclosure may be a soil that can be at least partially or even partially irrigated with brine to maintain plant growth.

As mentioned above, in some embodiments, the electromagnetic treatment can be carried out for a period of time sufficient to increase the relative energy state value of at least one of the nourishing elements in the at least one feedstock. A larger relative energy state value is sufficient (eg, this value and for a sufficient period of time) to allow the composition to improve the soil (when combined with the composition) to be irrigated by saline to support plant growth, with the soil Not compared when combined with the composition. In some embodiments, the electromagnetic treatment can be performed for a time sufficient to allow the energy spectrum of the composition to be sufficiently corrected (eg, sufficiently correct for the composition in a pre-existing state and retained for a sufficient period of time) such that the composition The ability to improve soil (when combined with the composition) by irrigation with saline to support plant growth is compared to when the soil is not combined with the composition.

"Brine" as used herein may be an aqueous solution, suspension or slurry comprising one or more salts, for example, comprising at least one salt selected from the group consisting of sodium, magnesium, calcium, potassium, chlorine, sulfur and bromine. . For example, the brine can be seawater, such as found in the Atlantic, Indian Ocean, and Pacific, and Mediterranean seas; or water from inland brine sources.

As previously mentioned, in some embodiments, the electromagnetic treatment can be carried out for a period of time sufficient to increase the relative energy state values of at least one of the nourishing elements in the at least one feedstock to obtain a composition as disclosed herein.

As used herein, "relative energy state value" refers to the magnetic induction of an element in a sample to be measured as found in a standard reference sample, such as a commercially available machine as described hereinafter. The ratio of the magnetic induction of the same elements in those standard reference samples). The magnetic induction of an element can be represented by the electrical signal output from the device, and the device can be amplified if needed. For any particular element, the standard reference samples may be the same or different for different comparison settings of the embodiments. In other words, different machines with different standard reference samples can be used for different elements. When different standards are used in different comparison settings (ie, may occur due to the use of different machines), the ratios obtained for the samples provided may be different for different elements, but the relative trends of those ratios of the samples provided should the same. However, in a single comparison setting of the sample (ie, when using a single machine as described herein for the provided sample), the standard reference sample for each particular element is a single reference standard. In a single comparison setting, the following standard reference samples were used for the elements N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo and Se in all samples: ammonium sulfate for N Use calcium phosphate monobasic for P, potassium chloride for K, calcium sulfate for Ca, magnesium sulfate for Mg, sulfur dioxide for S, copper sulfate for Cu, ferrous sulfate for Fe, sulfuric acid for Mn Manganese, zinc sulfate for Zn, boric acid for B, ammonium molybdate for Mo, and selenium dichloride for Se. In other words, in this single comparison setting, each element has a single reference standard, such as a single reference standard for N and a single reference standard for P.

Thus, the relative energy state value of an element indicates the relative value of the magnetic induction of the element in the sample to be measured (compared to the magnetic induction of the same element in the standard reference sample). The higher positive relative energy state value (ie, ratio) of the element indicates that the element in the sample to be measured has a higher potential than the same element in the standard reference sample, eg, its ability to transfer energy and/or The ability to be absorbed by plants.

For example, a quantum resonance spectrometer (QRS) can be used to measure the relative energy state values of an element, such as a TJQQ-1 quantum resonance spectrometer or a TJQ-D quantum resonance spectrometer, which is owned by Chongqing Tianjiquan Quantum Medical Development and Research Association (Chongqing Tianjiquan Quantum). Medical Development and Research Institute in China) is commercially available and commercially available; and J-1 quantum resonance spectrometer, which is commercially available from the Corporation Quantum Medical Research Institute of Japan. Each commercial source provides operational instructions for the machine being sold, such as the commercially available J-1 quantum resonance spectrometer from the Japan Institute of Quantum Medical Research and the experiments reported in Example 8. For the J-1 machine used here, the customized software is included with the machine.

As previously mentioned, in some embodiments, the electromagnetic treatment can be performed for a period of time sufficient to increase the relative energy state value of the at least one nourishing element to a relative energy state greater than the at least one nourishing element in the pre-existing state. The relative energy state value of the value. Similarly and as discussed in further detail below, in some embodiments, the electromagnetic treatment can be performed for a period of time sufficient to cause the energy spectrum of the composition to be more positive than the energy spectrum of the composition in a pre-existing state, and The corrected energy spectrum is sufficiently correct and lasts for a sufficient amount of time to achieve at least one of the objectives disclosed herein.

"Pre-existing state" as used herein refers to the nourishment element, or composition, or soil, or plant, or any part thereof (eg, seed), which was found prior to the treatment disclosed in the present disclosure. Self state (about relative energy state value). It may also be its own state (with respect to the energy spectrum) found in the composition or soil or plant, or any part thereof (eg, seed) prior to the treatment disclosed in the present disclosure.

As used herein, "energy spectrum" refers to the recording of the intensity and frequency of electromagnetic waves measured on a sample. For example, the RSA6000 series of optical spectrum analyzers (manufactured by Tektronix and commercially available) or the QFS-3401 biological organism weak magnetic field analyzer can be used (from Beijing Xianmai, China) Quantum Scientific Applied Technology Development Co., Ltd.) is commercially available to measure this energy spectrum and is shown in Figures 10A and 10B. Again, each commercial source provides operational instructions, and the QFS-3401 analyzer contains custom software.

In one aspect, the present disclosure is directed to a method for making a composition disclosed herein for improving the quality of soil, plant growth, seeds, and/or plant products. In one embodiment, the present disclosure is directed to a method of making a composition comprising performing an electromagnetic treatment on a composition in a pre-existing state. In another embodiment, the present disclosure is directed to a method of making a composition comprising performing electromagnetic treatment on at least one material comprising at least one nourishing element for a sufficient period of time to increase the relative energy state of the at least one nourishing element a value (compared to the relative energy state value of the at least one nutrient in the pre-existing state), and wherein the composition is modified by the relative energy state value of the at least one nourishing element (when combined with the composition) The ability to support plant growth is better than when the soil is not combined with the composition. In still another embodiment, the present disclosure is directed to a method of making a composition comprising performing electromagnetic treatment on at least one material comprising at least one nourishing element for a sufficient period of time to allow sufficient energy spectrum of the at least one material Correction (compared to the energy spectrum of the at least one material in the pre-existing state) such that the composition may improve the ability of the soil to support plant growth (when combined with the composition) due to a sufficiently correct energy spectrum, The soil is good when it is not combined with the composition.

The electromagnetic treatment can be performed on at least one of the materials disclosed herein by applying an electromagnetic field to a space in which at least one of the materials is placed, such as a container. The electromagnetic treatment can be carried out for a sufficient period of time to increase the relative energy state values of at least one of the nourishing elements in the at least one material to obtain a composition as disclosed herein. The composition thus obtained (as disclosed herein) can improve soil (when the soil is combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The compositions disclosed herein may also improve the ability of the soil (when combined with the compositions so disclosed) to be irrigated by seawater to support plant growth, as compared to when the soil is not combined with the composition. The compositions disclosed herein can also be used to improve plant growth by applying (e.g., by spraying) plants (such as agricultural plants). Also disclosed herein is an improved soil.

The electromagnetic treatment may be performed by applying an electromagnetic field (as described above) to at least one of the materials comprising at least one of the nourishing elements disclosed herein, by applying an electromagnetic field (such as a container) to a space in which the at least one material is placed. The electromagnetic treatment can be carried out for a sufficient period of time to allow the energy spectrum of the composition to be corrected sufficiently for a sufficient period of time and/or to increase the relative energy state value of the selected nourishing element for a sufficient period of time to achieve a useful achievement. At least one composition as the result disclosed herein. Sufficient instructions and details are provided herein so that those skilled in the art will be able to routinely combine the required machinery and parts to determine how to perform the electromagnetic treatment under certain conditions. The composition thus obtained (as disclosed herein) may be capable of improving soil (when the soil is combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The compositions disclosed herein may also be capable of improving the ability of the soil (when combined with the composition so disclosed) to support the growth of the plant by seawater (at least partially or exclusively), with the soil not being associated with the composition Compare when combined. The compositions disclosed herein may also be capable of improving plant growth by applying (by, for example, spraying) to plants, such as agricultural plants. An improved soil is also disclosed herein.

As used herein, "raw material" refers to a component that is used to make a composition as disclosed herein prior to energy treatment. As used herein, "composition" is generally referred to as a mixture of at least one starting material that has been treated by energy treatment (eg, electromagnetic treatment) as disclosed herein. "Constituent in a pre-existing state" as used herein generally refers to a mixture of at least one starting material present prior to such energy treatment.

Figure 2 graphically illustrates how electromagnetic treatment can be performed on at least one of the materials to make a composition as disclosed herein. First, at least one of the raw materials is loaded into a container. The container may contain, for example, an insulating substance. In one embodiment, the container is covered by an insulating outer layer. In some embodiments, the container can be closed or semi-closed (such as sealed or semi-sealed), for example, after being loaded with at least one material, further such as shadowing or semi-shadowing. Then, by generating an AC current, it is caused to flow through a processing apparatus to generate an electromagnetic field in the space in which the container (and at least one of the raw materials contained therein) is placed as described above to perform the electromagnetic treatment.

According to one embodiment disclosed herein, the processing device can be in the form of a coil. The coil can be wrapped around a container containing the at least one substance to be treated. According to another embodiment disclosed herein, the processing device can be in the form of an antenna. The antenna can be placed close to the container containing the substance to be treated, placed on a container containing the substance to be treated, inserted into a container containing the substance to be treated, or inserted into the substance to be treated. In some embodiments, the processing device can include a plurality of coils. In some embodiments, the processing device can include a plurality of antennas. The antenna can be arranged around a container containing the material.

In one embodiment, the electromagnetic treatment disclosed herein can include setting a target relative energy state value for at least one selected nourishing element in at least one of the materials, as shown in FIG. The at least one selected nourishing element may, for example, be selected from the group consisting of N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo, and Se. As a further embodiment, the at least one selected nourishing element can be selected from the group consisting of N, P, and K.

In some embodiments, the relative energy state value of the target can be set based on standard soil. In some embodiments, the relative energy state value of the target can be set according to the soil to which the target of the composition disclosed herein is applied. In one embodiment, the experiment can be carried out by observing the growth of various plants in the soil to which the target as disclosed herein is applied. In those experiments, the compositions disclosed herein have different relative energy state values for the selected nourishing elements to determine a target relative energy state value for each nutrient of interest that is more suitable for the target soil.

In some embodiments, the measurement can be performed on at least one substance to be treated prior to energy treatment to obtain a relative energy state value of at least one selected nourishing element in at least one substance to be treated. In some embodiments, measurements can be made using a QRS machine as described above. The target relative energy state value can be set, for example, based further on a relative energy state value of the nourishment element selected to be in a pre-existing state, such as when measured prior to processing.

A processing signal can then be generated based on the target relative energy state value, for example, by the machine performing the electromagnetic processing. In some embodiments, the processing signal broadly includes information regarding the processing length, and the frequency (Hz), voltage (V), and intensity (A (amperes)) of the processed AC current.

An AC current generator can be used to generate an AC current to flow in the processing device in accordance with the processing signal to generate an electromagnetic field for electromagnetic processing in an effort to achieve a target relative energy state value for the at least one selected nourishing element. See Figure 2. The AC current generator can be a single generator. Furthermore, the AC current generator can include a plurality of generators for generating AC currents of different frequencies. For example, the AC current generator can include an ultra low frequency generator for generating an AC current having a frequency of from about 0.001 Hz to about 1 kHz for generating an AC current having a frequency of from about 1 kHz to about 1 megahertz. a low frequency generator for generating a video generator having an AC current having a frequency of about 20 Hz to about 10 megahertz for generating a high frequency with an AC current having a frequency of about 200 kHz to about 30 megahertz a very high frequency generator for generating an AC current having a frequency of about 30 megahertz to about 300 megahertz, and an ultra high frequency generator for generating an AC current having a frequency higher than about 300 megahertz .

In some embodiments, the supply voltage applied to the AC current generator to generate the AC current can be set to a normal citizen use voltage, such as from about 110 volts to about 220 volts. More particularly, in some embodiments, the supply voltage can be about 200 volts or 240 volts. In some embodiments, the supply voltage can be about 220 volts. In some embodiments, the supply voltage can be from about 110 volts to about 120 volts.

In some embodiments, the operating voltage applied to the processing device can range from about 5 volts to about 220 volts. For example, in some embodiments, the operating voltage can be from about 10 volts to about 15 volts.

In some embodiments, the intensity of the AC current can be selected from about 0.02 amps to about 40 amps. More particularly, in some embodiments, the intensity of the AC current can be selected from about 12 amps to about 20 amps. In some embodiments, the AC current can have an intensity of about 36 amps. In some embodiments, the intensity of the AC current can be selected from about 0.06 amps to about 6 amps.

In some embodiments, the AC current for electromagnetic processing has a frequency in the range of from about 20 Hz to about 50,000 Hz, such as from about 25 Hz to about 10,000 Hz, and further such as from about 25 Hz to about 1000 Hz. In one embodiment, the AC current used for electromagnetic processing has a frequency of 900 Hz.

In some embodiments, the frequency of the AC current can be varied during electromagnetic processing, for example, from about 25 Hz to about 10,000 Hz, such as from about 25 Hz to about 1000 Hz, or such as from about 500 Hz to about 1500 Hz. In some embodiments, the frequency of the AC current can be fixed, for example, at 900 Hz, 600 Hz, 700 Hz, 800 Hz, and 1000 Hz during electromagnetic processing. The voltage and intensity of the AC current may remain fixed or changeable during electromagnetic processing.

In some embodiments, the length of the electromagnetic process can be set based on the target relative energy state value. In some embodiments, the length of the electromagnetic treatment can also be set based on ambient temperature and/or humidity. For example, in general, the higher the temperature and/or humidity, the shorter the treatment length. In some embodiments, the electromagnetic treatment can be from about 25 minutes to about 2 hours in length. In one embodiment, the electromagnetic treatment can be about 1 hour in length. In one embodiment, the electromagnetic treatment can be about 45 minutes in length. In one embodiment, the electromagnetic treatment can be about 2 hours in length, and the treatment can be applied three times with a four hour pause between treatments.

In some embodiments, the electromagnetic treatment can be performed in two stages. In the first phase, the AC current frequency for the electromagnetic treatment can be gradually changed from about 25 Hz to about 1000 Hz while the voltage and intensity of the AC current remain fixed. In the second phase, the frequency of the AC current can be gradually changed from about 1000 Hz to about 10,000 Hz while the voltage and intensity of the AC current remain fixed.

The length of the first stage can range from about 20 minutes to about 45 minutes. The length of the second stage may be the difference between the length of the treatment as set in the processing signal and the length of the first stage, and the length of the second stage may generally range from about 75 minutes to about 100 minutes. In one specific example, there is no need to pause between the completion of the first phase and the beginning of the second phase.

As mentioned above, the composition in a pre-existing state contains at least one starting material. If there is only one such composition, the method can proceed to the next step, which can be a measure of the relative energy state value after processing. If there is more than one composition (as set forth herein as a secondary composition), at least one of the at least one starting material of the secondary composition is treated and the other is selectively treated.

A relative energy state value of at least one selected nourishing element in at least one of the raw materials as processed or in a mixture of secondary compositions that have been treated can be measured using, for example, a QRS machine, as described above and as in Example 8. Presented in more detail. The relative energy state value can be compared to the target relative energy state value to see if the relative energy state value of the at least one selected nourishment element has increased to meet or exceed the target relative energy state value, as shown in FIG. in. If so, it may be decided to have obtained a composition as disclosed herein, which possesses at least one of the capabilities mentioned herein, and the method ends. If not, the electromagnetic treatment can be repeated as described above as many times as needed until the relative energy state value of the selected nourishing element has increased to meet or exceed the target relative energy state value.

Furthermore, the method disclosed herein may not use a target relative energy state value to determine when to stop repeating the electromagnetic process. In one embodiment, as shown in Figure 3, secondary electromagnetic processing can be performed sequentially. The relative energy state values of the selected nourishing elements can be measured after each treatment. Comparing the relative energy state values of the nourishing elements selected after the second successive processing to see if the second processing of the second sequential processing further increases the relative energy state value of the selected nourishing element by some amount or any amount . For example, the relative energy state value of the selected nourishing element after the second treatment (the value 2 in Figure 3) and the relative energy state value of the selected nourishing element after the first treatment can be compared (in the first 3 in the figure, the value is 1) to see if the value 2 - value 1 is satisfied. A condition of a preselected threshold, wherein the preselected threshold is a non-negative value. If so, it may be decided to have obtained a composition as disclosed herein, which possesses at least one of the capabilities mentioned herein (as mentioned above), and the method ends. If not, it is possible that the relative energy state value of the selected nourishing element can be further increased, so that the electromagnetic treatment can be repeated as many times as needed until the desired result is achieved, or until the decision will not achieve the desired result. The interval between secondary sequential treatments can be, for example, from about 2 hours to about 5 hours, such as about 4 hours.

In certain embodiments, a composition as disclosed herein can comprise more than one secondary composition. In some embodiments, the feedstock can comprise at least a first feedstock to the first composition used to make the composition, and a second component feedstock second feedstock used to make the composition. As mentioned above, at least one of the starting materials of each sub-composition can be treated with or without electromagnetic treatment. In one embodiment, a composition as disclosed herein can comprise three sub-compositions. At least one of the materials used for the first, second, and third compositions may be referred to as first, second, and third materials, respectively. The first and second materials may each be electromagnetically treated to obtain the first and second compositions. The third material may be untreated and used directly as a third composition, or it may be treated.

In one embodiment, as shown in Figures 4A and 4B, the first and second materials can each be loaded into two containers and individually electromagnetically treated as disclosed herein. The first and second compositions are obtained separately. In some embodiments, the first material can be loaded into a container and electromagnetically processed to obtain the first composition. The container can then be emptied and the second material loaded into the container and electromagnetically processed to obtain the second composition. The first, second, and untreated third compositions can then be mixed at certain ratios. For example, the weight percentages of the first, second, and third compositions in the mixture can be 15%, 15%, and 70%, respectively, relative to the total weight of the composition. A relative energy state value of the selected nourishing element of the mixture can be compared to a target relative energy state value (which can be set as disclosed herein) to see if the relative energy state value meets or exceeds the target relative energy state value. . If so, it may be decided to have obtained a composition as disclosed herein, which possesses at least one of the capabilities mentioned herein, and the method ends. If not, some amount of the first composition, which can be obtained by electromagnetic treatment on a first material as disclosed herein, is added to the mixture and repeated measurements and comparisons are required. If the relative energy state value of the selected nourishing element reaches or exceeds the target relative energy state value, it may be decided that the composition as disclosed herein has been obtained, which possesses at least one of the capabilities mentioned herein, and the method ends . In other aspects, certain amounts of the second composition, which can be obtained by electromagnetic treatment on a second material as disclosed herein, are added to the mixture and measured and compared again. If the relative energy state value of the selected nourishing element reaches or exceeds the target relative energy state value, it may be decided that the composition as disclosed herein has been obtained, which possesses at least one of the capabilities mentioned herein, and the method ends . In other aspects, a short period of time (e.g., 10 minutes) of electromagnetic treatment can be performed on the mixture, and measurements can be taken again to see if a goal as disclosed herein has been achieved.

In certain embodiments, the feedstock can be in liquid form prepared by dissolving or suspending various ingredients in a solvent such as water. The various ingredients may include, for example, agricultural grade amino acids, copper sulfate, zinc sulfate, manganese sulfate, boric acid, potassium sulfate, and 5-ALA. A mixer can be used to stir the solution while dissolving the ingredients. The mixer speed can be set from 10 r/min to 100 r/min (eg, 50 r/min).

In some embodiments, the electromagnetic treatment can be performed when the components are dissolved or suspended in a solvent and the solution is stirred. In some embodiments, the electromagnetic treatment can be performed after the dissolution process is completed. The electromagnetic treatment can be carried out for about 10 minutes to about 1 hour (for example, about 45 minutes). The frequency of the AC current can vary, for example, from about 25 Hz to about 10,000 Hz, such as from about 500 Hz to about 1500 Hz. The operating voltage applied to the processing device can range from about 5 volts to about 220 volts (eg, from about 10 volts to about 15 volts). The intensity of the AC current can be selected from about 0.05 amps to about 40 amps (eg, from about 0.06 amps to about 6 amps).

As described above, the relative energy state values of the selected nourishing elements can be used to determine the utility of the electromagnetic treatment. In another embodiment, the relative energy state values of the plurality of selected nourishing elements can be used to determine the utility of the electromagnetic treatment. In some embodiments, the relative energy state value of the selected nourishing element can be set, and the electromagnetic treatment can be repeated until some or all of the selected nourishing elements have a relative energy state value after one treatment. Increased to achieve or exceed the respective target relative energy state values. In other embodiments, the electromagnetic treatment may be repeated as needed until the difference between the respective relative energy state values of some or all of the selected nourishing elements after the secondary sequential processing is less than or equal to a predetermined threshold. .

In some embodiments, the electromagnetic treatment can be performed under certain combinations of conditions without deciding when to stop processing; that is, in other words, the process simply proceeds for a certain period of time without stopping to measure the effect of the process until The process ends. For example, the electromagnetic treatment can be carried out at an operating voltage of from about 10 volts to about 15 volts, an AC current intensity of from about 0.06 amps to about 6 amps, and a time of about 45 minutes. During processing, the AC current frequency can be gradually changed from about 500 Hz to about 1500 Hz at a fixed rate of increase.

After the electromagnetic treatment, routine experiments can be used to determine whether the composition improves the soil and/or plant growth in the soil when applied to the target soil. A portion of the composition can be mixed with the target soil sample at a selected ratio to obtain a mixture. This ratio can also be determined by routine experimentation using routine experimentation. For example, 2 grams of the composition disclosed herein can be mixed with 10 grams of the target soil to obtain a mixture; in this case, the weight ratio of the composition in the mixture to the target soil is 1:5. Further for example, the weight ratio of the composition in the mixture to the target soil may range from 1:5,000 to 1:1, such as, for example, 1:2,500, 1:1,000, 1:800, 1:500, 1:250 , 1:100, 1:90, 1:80, 1:70, 1:60, 1:50, 1:40, 1:30, 1:20, 1:10 or 1:1. The energy spectrum (as described above) and the evaluation of the mixture of soil and composition can then be measured using, for example, a spectral analyzer to see if the energy spectrum of the mixture of soil and composition is more post-treatment than disclosed herein. The energy spectrum of the target soil before the composition is corrected. See, for example, Figures 7A and 7B and Figures 10A and 10B. If the obtained energy spectrum is corrected, it is more likely that the treated soil will be a good candidate for improving plant growth, based on the experience of the inventor.

In certain embodiments, if the treated soil system is a good candidate for improving plant growth, the compositions disclosed herein can be applied, for example, in an amount measured relative to the area of the soil with respect to the weight of the composition, such as For example, the number of kilograms of this composition per acre or per "acre" or per hectare (1 hectare of 10,000 square meters or 15 acres) is further discussed below.

In some embodiments, the machine patterns shown, for example, in Figures 10A and 10B are used, as measured energy spectra can be compared to, for example, the standard energy spectrum of standard soil to see if they match each other. As used herein, "matching" means that after the combination of the composition and the target soil, the measured energy spectrum is substantially the same as or similar to the target energy spectrum of the target soil, or at least sufficiently positively Improvements have attained at least one of the objectives disclosed herein, such as improving soil and/or improving the ability of plants to grow in treated soil. For example, if the measured energy spectrum of the treated mixture matches the target energy spectrum (eg, if the total area under the positive curve of the treated mixture equals or even exceeds the total energy spectrum of the target soil) When it is determined, it is determined that the composition has effectively improved the target soil. Those skilled in the art can further refine the "matching" by adjusting the weight ratio of the mixture based on a comparison of the energy spectrum of the treated mixture with the energy spectrum of the target soil through routine experimentation.

In some embodiments, the measured energy spectrum of the treated mixture can be compared to the energy spectrum of the target soil prior to mixing with the composition to see if the energy spectrum of the mixture has the same area under the positive curve. The total amount or more, as compared to the energy spectrum of the target soil prior to mixing with the composition. If so, it can be determined that the composition has effectively improved the target soil, even though the two spectra are not identical as explained above.

In other typical embodiments, the substitution compares the energy spectrum of the mixture to the target energy spectrum to measure a relative energy state value of one or more selected nourishing elements in the mixture and a comparison with a reference relative energy state value, To determine if the composition should be able to improve the target soil. The reference relative energy state value as used herein may be the relative energy state value of the one or more selected nourishing elements in the standard soil, or may be higher than the one or more selected nourishes in the standard soil. The value of the relative energy state value of the element. Furthermore, in some embodiments, the effective relative energy state values of the nourishing elements can be determined by observing the growth of the plants in the soil of the sample. The reference relative energy state value can then be set empirically by empirically determining one or more relative energy state values.

In some embodiments, instead of evaluating the relative energy state values of one or more nourishing elements, the energy spectrum of the treated material can be used to determine the utility of the electromagnetic treatment, and the methods disclosed above can be used. For example, in some embodiments, the energy of the spectral composition can be set based on the energy spectrum of the standard soil, the target soil, the feedstock, or any combination thereof. If necessary, repeating the electromagnetic treatment until the energy spectrum of the composition has become positive or more positive than the energy spectrum of the target (eg, by measuring the total area under the positive curve of the treated mixture), or at least Be sufficiently correct to consider combining with the target soil to achieve the desired improvement candidate. In some embodiments, the electromagnetic treatment is repeated as needed until the difference in energy spectra of the composition after secondary processing is less than or equal to a predetermined value, similar to the discussion above regarding relative energy state values.

In another aspect, the present disclosure is directed to a composition made by performing an electromagnetic treatment as disclosed herein.

In certain embodiments, the composition can be made by electromagnetic treatment on at least one of the materials used to make the composition, using methods as disclosed herein. The at least one raw material used to make the composition may comprise at least one nourishing element.

In some embodiments, the feedstock can comprise at least a first feedstock used to make the first composition of the composition, and a second feedstock used to make the second composition of the composition. The first material may comprise at least one organic acid as defined above comprising at least one first nourishing element. The second raw material may comprise at least one photosensitive substance as defined above, comprising at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance, wherein the at least one first and second nourishing elements Can be the same or different. And the second raw material may further comprise at least one organic acidic substance different from the at least one photosensitive material.

The composition can be made by electromagnetic treatment on at least one of the first and second materials (i.e., a chemical tool for absorbing electromagnetic energy) and then mixing them together, as disclosed herein.

In some embodiments, the material used to make the composition may further comprise a third material used to make the third composition of the composition. The third raw material may comprise at least one organic basic substance as defined above, optionally comprising at least one third nourishing element, the at least one third nourishing element being the same as or different from the at least one first and second nourishing elements, and At least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance.

The composition can be electromagnetically treated on at least one of the first, second and third materials (i.e., a chemical tool for absorbing electromagnetic energy) using a method as disclosed herein, and then mixed Together, it is manufactured by manufacturing this composition.

As mentioned above, the present disclosure relates to a composition comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, A larger relative energy state value is sufficient for the composition to improve soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be sufficiently modified to allow the plants grown therein to be fully or partially irrigated with saline. "Partially" or "partially" as used herein means the use of a combination of saline and non-saline water under irrigation conditions. For example, saline can be used in an amount of 10-90% of the total volume of water that can be applied to the plant, and can be applied alone or mixed with normal water when the application is performed.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than the pre-existing state. a relative energy state value of a nourishing element, the larger relative energy state value being sufficient and lasting for an effective period of time to improve the soil (when combined with the composition) to support plant growth, compared to the soil when the composition is not Good combination.

The present disclosure also relates to an improved soil comprising at least one nourishing element, wherein the at least one nourishing element (ie, a chemical tool that has absorbed electromagnetic energy) has a relative energy state value that is sufficiently greater than a pre-existing state in the soil. The relative energy state value of at least one of the nourishing elements, and the modified soil therein, may have the ability to support plant growth due to a sufficiently large relative energy state value, which is better than the soil in the pre-existing state.

The present disclosure also relates to an improved plant for treating a plant with a composition comprising at least one nourishing element (ie, a chemical tool that has absorbed electromagnetic energy) in an effective amount, wherein the relative energy possessed by the at least one nourishing element a state value greater than a relative energy state value of the at least one nourishing element in the pre-existing state, and wherein the composition may improve the plant treated with the composition due to a sufficiently large relative energy state value (and without the composition) Treated plants are compared).

The present disclosure also relates to an improved plant made by treating the plant with an effective amount of a composition comprising at least one nourishing element (ie, a chemical tool that has absorbed electromagnetic energy), wherein the energy spectrum possessed by the composition The energy spectrum of the composition in the pre-existing state is more correct, and the composition therein may modify the plants treated with the composition (as compared to plants not treated with the composition) due to the corrected energy spectrum.

The present disclosure also relates to an improved seed and/or improved from a plant grown in an improved soil treated with an effective amount of a composition comprising at least one nourishing element (ie, a chemical tool that has absorbed electromagnetic energy). Plant product (including improved quality of a plant product), wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger relative energy The state value is sufficient and lasts for an effective period of time to modify the soil (when combined with the composition) to produce a plant grown therein that provides improved seed and/or improved plant product (without Comparison of plants grown in improved soil).

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant treated with a composition comprising at least one nourishing element, wherein the composition possesses an energy spectrum that is more pre-existing in composition. The energy spectrum of the object is corrected, the corrected energy spectrum is sufficient and lasts for a sufficient period of time to adequately modify the composition to produce a plant grown therein that provides improved seed and/or plant product (without Comparison of plants treated with the composition).

The present disclosure also relates to a composition comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger relative energy The state value is sufficient and lasts for a period of time sufficient for the composition to improve the virgin soil (when combined with the composition) to support plant growth, which is better than the virgin soil when not combined with the composition, wherein the virgin soil Plant growth cannot be supported prior to binding to the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated (in whole or in part) by saline.

The present disclosure also relates to an improved virgin soil treated with an effective amount of a composition comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than the relative state of the at least one nourishing element in the pre-existing state. An energy state value that is sufficient to improve the soil (when combined with the composition) to improve plant growth (relative to virgin soil not treated with the composition).

The present disclosure also relates to an improved virgin soil comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value that is sufficiently greater than a relative energy state value of at least one nourishing element pre-existing in the virgin soil. To improve plant growth, which is better than the virgin soil in the pre-existing state.

The present disclosure also relates to an improved plant produced by growing the plant in an improved virgin soil treated with an effective amount of a composition comprising at least one nourishing element (ie, a chemical tool that has absorbed electromagnetic energy), Wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger relative energy state value being sufficient to improve the plant grown in the modified soil Plant growth (compared to plants that are not grown in the modified virgin soil).

The present disclosure also relates to an improved plant produced by growing the plant in a modified virgin soil comprising at least one nourishing element, wherein the at least one nourishing element possesses a relative energy state value greater than that in the virgin soil a relative energy state value of at least one of the trophozoites in a pre-existing state and for a period of time sufficient to improve plant growth of plants grown in the modified soil (compared to plants not grown in the modified virgin soil) ).

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in a modified virgin soil treated with an effective amount of a composition comprising at least one nourishing element, wherein the at least one nourishing element The relative energy state value possessed is greater than the relative energy state value of the at least one nourishing element in the pre-existing state, the larger relative energy state value being sufficient and lasting for a sufficient period of time to produce a plant grown therein, which provides Improved seed and/or plant product (compared to plants not grown in the modified virgin soil).

The present disclosure also relates to a composition comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of at least one nourishing element in a pre-existing state, the larger relative energy state The value is sufficient to allow the composition to convert soil selected from sand/loamy sand, heavy clay, clay, sandy clay, sandy clay loam, silty clay, silty clay loam and silt loam to Modified soil selected from sandy loam, loamy clay, clay loam, and loam (when the soil is combined with the composition). The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated (in whole or in part) by saline.

The present disclosure also relates to a modified soil selected from the group consisting of sandy loam, loamy clay, clay loam, and loam soil, comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger relative energy state value being sufficient to allow the composition to be selected from sand/loar sand, heavy clay, clay, sandy clay, The soil of sandy clay loam, silty clay, silty clay loam and silt loam is converted into modified soil selected from sandy loam, loamy clay, clay loam and loam, when the soil and the composition When the matter is combined.

The present disclosure also relates to an improved soil comprising at least one nourishing element selected from the group consisting of sandy loam, loamy clay, clay loam and loam, wherein the at least one nourishing element possesses a relative energy state value greater than or greater than Relative to at least one nourishing element in the pre-existing state of sand/loamy sand, heavy clay, clay, sandy clay, sandy clay loam, silty clay, silty clay loam and silt loam soil Energy state values to support plant growth, the ratio being selected from sand/loamy sand, heavy clay, clay, sandy clay, sandy clay loam, silty clay, silty clay loam and silt loam The pre-existing state of the soil is good.

The present disclosure also relates to an improved plant grown by modifying soil in a soil selected from the group consisting of sandy loam, loamy clay, clay loam and loam and treated with a composition comprising at least one nourishing element. Generating, wherein the at least one nourishing element possesses a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger relative energy state value being sufficient to improve in the modified soil Growing plants (compared to plants that are not grown in the modified soil).

The present disclosure also relates to an improved plant produced by growing the plant in an improved soil selected from the group consisting of sandy loam, loamy clay, clay loam and loam and comprising at least one nourishing element, wherein the The relative energy state value of a nourishing element is greater than that selected from sand/loamy sand, heavy clay, clay, sandy clay, sandy clay loam, silty clay, silty clay loam and silt The relative energy state values of at least one of the trophozoites in a pre-existing state in the loam soil to improve the plants grown in the modified soil (compared to plants not grown in the modified soil).

The present disclosure also relates to an improved seed produced from a plant grown in modified soil selected from the group consisting of sandy loam, loamy clay, clay loam and loam and treated with a composition comprising at least one nourishing element and/or Or a modified plant product, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger relative energy state value being sufficient for the composition Converting soil selected from sand/loamy sand, heavy clay, clay, sandy clay, sandy clay loam, silty clay, silty clay loam and silt loam to be selected from sandy loam Improved soil of loamy clay, clay loam and loam (when the soil is combined with the composition), and plants in which the growth is provided provide improved seeds and/or plant products (and without the composition) Treated plants are compared).

The present disclosure also relates to a composition comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger relative energy The state value is sufficient for the composition to convert non-loar soil into loam (when the soil is combined with the composition). The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to a composition comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger relative energy The state value is sufficient to allow the composition to improve the soil (when combined with the composition) to support the growth of the plant by saline irrigation, as compared to when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved loam treated with an effective amount of a composition comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy of the at least one nourishing element in the pre-existing state. A state value that is sufficient to convert the loam-free soil into loam (when the soil is combined with the composition).

The present disclosure also relates to an improved loam comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger The relative energy state value is sufficient to convert the loam-free soil into loam (when the soil is combined with the composition).

The present disclosure also relates to an improved soil produced by treating soil with a composition comprising at least one nourishing element in an effective amount, wherein the at least one nourishing element has a relative energy state value greater than the pre-existing state of at least one nourishing element a relative energy state value sufficient to improve the soil (when combined with the composition) is fully or partially irrigated with saline to support plant growth, as compared to when the soil is not combined with the composition .

The present disclosure also relates to an improved soil comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger The relative energy state value is sufficient to improve the soil (when combined with the at least one nutrient) to be irrigated by saline to support plant growth, as compared to when the soil is not combined with the at least one nutrient.

The present disclosure also relates to an improved plant produced by growing the plant in a modified loam treated with an effective amount of a composition comprising at least one nourishing element, wherein the relative energy state value possessed by the at least one nourishing element a relative energy state value greater than the at least one trophic element in the pre-existing state, the larger relative energy state value being sufficient to improve the plant grown in the modified soil (with plants not grown in the modified soil) Compare).

The present disclosure also relates to an improved plant produced by growing the plant with improved loam comprising at least one nourishing element, wherein the at least one nourishing element possesses a relative energy state value greater than the pre-existing state A relative energy state value of at least one nourishing element sufficient to improve the plant treated with the improved soil (compared to plants not grown in the modified soil).

The present disclosure also relates to an improved plant produced by growing the plant in a modified soil treated with an effective amount of a composition comprising at least one nourishing element, wherein the relative energy state possessed by the at least one nourishing element a value greater than a relative energy state value of the at least one nourishing element in the pre-existing state, the larger relative energy state value being sufficient to modify the plant treated with the modified soil and all or partially irrigated with saline (and not Comparison of plants grown in improved soil).

The present disclosure also relates to an improved plant produced by growing the plant with modified soil comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than the pre-existing state A relative energy state value of at least one of the nourishing elements, the larger relative energy state value being sufficient to improve the plant treated with the modified soil and irrigated with saline, compared to plants not grown in the modified soil.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in an improved loam treated with an effective amount of a composition comprising at least one nourishing element, wherein the at least one nourishing element Having a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger relative energy state value being sufficient for the plant grown therein to produce improved seeds and/or improved plants Product (compared to plants that are not grown in the modified soil).

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in an improved soil treated with an effective amount of a composition comprising at least one nourishing element, wherein the at least one nourishing element Having a relative energy state value greater than a relative energy state value of the at least one trophozoic element in a pre-existing state, the larger relative energy state value being sufficient for growth in a plant grown therein and wholly or partially irrigated by saline Seeds and / or plant products (compared to plants not grown in the modified soil).

The present disclosure also relates to a composition comprising a first composition comprising at least one organic acidic substance and a second composition comprising at least one photosensitive material, wherein the first composition and the second composition At least one of the at least one first nourishing element, wherein the at least one photosensitive material is different from the at least one organic acidic substance, and further wherein the at least one first nourishing element possesses a relative energy state value greater than the pre-existing state a relative energy state value of at least one first nourishing element, the greater relative energy state value of the at least one first nourishing element being sufficient to allow the composition to improve soil (when combined with the composition) to support plant growth, the ratio The soil is good when it is not combined with the composition.

The composition may further comprise a third composition comprising at least one organic base material (optionally comprising at least one third nourishing element), the at least one third nourishing element being the same as or different from the at least one first nourishing element And the at least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance. The at least one third nourishing element of the organic base material may have a relative energy state value greater than a relative energy state value of the at least one third nourishing element in the pre-existing state, the greater relative energy of the at least one third nourishing element A state value is sufficient that alone or in combination with the at least one first nourishing element can improve soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated (in whole or in part) by saline.

The present disclosure also relates to an improved soil for treating soil by including in its effective amount a composition comprising a first composition comprising at least one organic acid and a composition comprising a second composition comprising at least one photosensitive material. Manufactured, wherein at least one of the first composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitive substance is different from the at least one organic acidic substance, and further wherein the at least one first The relative energy state value possessed by the nourishing element is greater than the relative energy state value of the at least one first nourishing element in the pre-existing state, and the greater relative energy state value of the at least one first nourishing element is sufficient to improve the soil (when the composition is When the substance is combined, it supports plant growth, which is better than when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a first composition comprising at least one organic acidic material and a second composition comprising at least one photosensitive material, wherein the first composition and the second time At least one of the compositions comprising at least one first nourishing element, wherein the at least one photosensitive material is different from the at least one organic acidic substance, and further wherein the at least one first nourishing element possesses a relative energy state value greater than the a relative energy state value of at least one first nourishing element in the presence state, the greater relative energy state value of the at least one first nourishing element being sufficient to support the plant growth (when the secondary composition is included), The soil is good when it does not contain the secondary composition.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising: a first composition comprising at least one organic acid, the organic acid comprising at least one first nourishment An element comprising: a second composition comprising at least one photosensitive material, the photosensitive material comprising at least one second nourishing element, the at least one photosensitive material being different from the at least one organic acidic substance, wherein the at least one first And the second nourishing element may be the same or different, and further wherein at least one of the first and second nourishing elements has a relative energy state value greater than a relative value of the at least one of the first and second nourishing elements in the pre-existing state An energy state value, the greater relative energy state value of at least one of the first and second nourishing elements is sufficient and lasts for a time sufficient to enable the composition to improve the soil (when combined with the composition) to support plant growth It is better than the soil when it is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising a first composition comprising at least one organic acidic substance, the organic acidic substance comprising at least one first nourishing element; and one comprising at least one a second composition of the photosensitive material, the photosensitive material comprising at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance, wherein the at least one first and second nourishing elements are the same Or different, and further wherein at least one of the first and second nourishing elements possesses a relative energy state value greater than a relative energy state value of at least one of the first and second nourishing elements in a pre-existing state, the first And a greater relative energy state value of at least one of the second nourishing elements is sufficient and lasts for a sufficient period of time to enable the composition to improve the soil (when combined with the composition) to support plant growth, which is less than the soil Good combination with the composition.

The present disclosure also relates to an improved plant produced by growing the plant in an improved soil treated with an effective amount of a composition comprising: a first composition comprising at least one organic acidic substance and a second composition comprising at least one photosensitive material, wherein at least one of the first composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitive material and the at least one organic The acidic substance is different, and further wherein the at least one first nourishing element has a relative energy state value greater than a relative energy state value of the at least one first nourishing element in a pre-existing state, the at least one first nourishing element being larger The relative energy state values are sufficient to improve the plants grown in the modified soil and all or part of which are irrigated by saline, as compared to plants that are not grown in the modified soil.

The present disclosure also relates to an improved plant produced by treating the plant with an effective amount of a composition comprising: a first composition comprising at least one organic acidic material and a first photosensitive composition comprising at least one photosensitive material a second composition, wherein at least one of the first composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitive substance is different from the at least one organic acidic substance, and further wherein The relative energy state value possessed by the at least one first nourishing element is greater than the relative energy state value of the at least one first nourishing element in the pre-existing state, the larger relative energy state value of the at least one first nourishing element being sufficient for improvement The plants treated with the composition are compared to plants not treated with the composition.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant treated with an effective amount of a composition comprising: a first composition comprising at least one organic acid and one comprising at least a second composition of a photosensitive substance, wherein at least one of the first composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitive substance is different from the at least one organic acidic substance And further wherein a relative energy state value possessed by the at least one first nourishing element is greater than a relative energy state value of the at least one first nourishing element in the pre-existing state, a greater relative energy state of the at least one first nourishing element The value is sufficient and lasts for a period of time sufficient for the treated plant to produce improved seeds and/or improved plant products for comparison with plants that are not grown in the modified soil.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in a modified soil comprising a composition, the composition comprising a first time comprising at least one organic acid a composition comprising: at least one first nourishing element; and a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishing element, the at least one photosensitive substance and the The at least one organic acid substance is different, wherein the at least one first and second nourishing elements may be the same or different, and further wherein at least one of the first and second nourishing elements has a relative energy state value greater than the pre-existing state a relative energy state value of at least one of the first and second nourishing elements, the greater relative energy state value of at least one of the first and second nourishing elements being sufficient and lasting for a sufficient period of time for the treated plant to produce Improved seeds and/or improved plant products compared to plants not grown in the modified soil

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant treated with a composition comprising a first composition comprising at least one organic acid, the organic acid And comprising a second composition comprising at least one photosensitive material, the photosensitive material comprising at least one second nourishing element, the at least one photosensitive material being different from the at least one organic acidic substance, Wherein the at least one first and second nourishing elements may be the same or different, and further wherein at least one of the first and second nourishing elements possesses a relative energy state value greater than the first and second nourishment in the pre-existing state a relative energy state value of at least one of the elements, the greater relative energy state value of at least one of the first and second nourishing elements being sufficient and lasting for a sufficient period of time for the treated plant to produce improved seeds and/or Improved plant products compared to plants not treated as such.

The present disclosure also relates to a composition comprising a first composition comprising at least one organic acidic material, the organic acidic material comprising at least one first nourishing element; and a second composition comprising at least one photosensitive material The photosensitive material comprises at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance, wherein the at least one first and second nourishing elements may be the same or different, and further wherein the first And a relative energy state value possessed by at least one of the second nourishing elements greater than at least one of the first and second nourishing elements in the pre-existing state, at least one of the first and second nourishing elements The greater relative energy state value is sufficient to enable the composition to improve soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition.

The composition may further comprise a third composition comprising at least one organic base material, optionally comprising at least one third nourishing element, the at least one third nourishing element being the same as the at least one first and second nourishing elements Or different, and the at least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance. The at least one third nourishing element of the organic base material has a relative energy state value greater than a relative energy state value of the at least one third nourishing element in a pre-existing state, a larger relative energy state of the at least one third nourishing element A value is sufficient that alone or in combination with at least one of the first and second nourishing elements can improve the soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated (in whole or in part) by saline.

The present disclosure also relates to a composition comprising a first composition comprising at least one organic acidic material and a second composition comprising at least one photosensitive material, wherein the first composition and the second composition At least one of the at least one species comprising at least one first nourishing element, wherein the at least one photosensitive material is different from the at least one organic acidic substance, and further wherein the at least one first nourishing element possesses a relative energy state value greater than the pre-existing a relative energy state value of at least one first nourishing element of the state, the greater relative energy state value of the at least one first nourishing element being sufficient to enable the composition to improve soil (when combined with the composition) in whole or in part The ability of saline irrigation to support plant growth is compared to when the soil is not combined with the composition.

The composition may further comprise a third composition comprising at least one organic base material, optionally comprising at least one third nourishing element, the at least one third nourishing element being the same as or different from the at least one first nourishing element, And the at least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance. The at least one third nourishing element of the organic base material has a relative energy state value greater than a relative energy state value of the at least one third nourishing element in a pre-existing state, a larger relative energy state of the at least one third nourishing element A sufficient value, either alone or in combination with at least one of the first and second nourishing elements, to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, and the soil is not The compositions were compared when combined. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising a first composition comprising at least one organic acidic material, the organic acidic material comprising at least one a trophic element; and a second composition comprising at least one photosensitive material, the photosensitive material comprising at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance, wherein the at least one The first and second nourishing elements may be the same or different, and further wherein at least one of the first and second nourishing elements has a relative energy state value greater than at least one of the first and second nourishing elements in the pre-existing state a relative energy state value, the greater relative energy state value of at least one of the first and second nourishing elements is sufficient to improve the soil (when combined with the composition) to support plant growth, which is not It is good when the composition is combined.

The present disclosure also relates to an improved soil comprising a composition comprising a first composition comprising at least one organic acidic substance, the organic acidic substance comprising at least one first nourishing element; and one comprising at least one a second composition of the photosensitive material, the photosensitive material comprising at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance, wherein the at least one first and second nourishing elements are the same Or different, and further wherein at least one of the first and second nourishing elements possesses a relative energy state value greater than a relative energy state value of at least one of the first and second nourishing elements in a pre-existing state, the first And a greater relative energy state value of at least one of the second nourishing elements is sufficient to enable the composition to improve the soil (when combined with the composition) to support plant growth, when the soil is not combined with the composition it is good.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising a first composition comprising at least one organic acidic material and a composition comprising at least one photosensitive material. a second composition, wherein at least one of the first composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitive substance is different from the at least one organic acidic substance, and further wherein The relative energy state value possessed by the at least one first nourishing element is greater than the relative energy state value of the at least one first nourishing element in the pre-existing state, and the greater relative energy state value of the at least one first nourishing element is sufficient to improve the soil (When combined with the composition) all or part of the irrigation is supported by saline to support plant growth, as compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising a first composition comprising at least one organic acidic material and a second composition comprising at least one photosensitive material, wherein the first At least one of the primary composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitive material is different from the at least one organic acidic substance, and further wherein the at least one first nourishing element possesses The relative energy state value is greater than a relative energy state value of the at least one first nourishing element in the pre-existing state, the greater relative energy state value of the at least one first nourishing element being sufficient to enable the composition to improve the soil (when The ability of the composition to be fully or partially irrigated by saline to support plant growth when combined with the soil is compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved plant produced by growing the plant in an improved soil treated with an effective amount of a composition comprising a first composition comprising at least one organic acid. The organic acid substance comprises at least one first nourishing element; and a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishing element, the at least one photosensitive substance and the at least one An organic acidic substance, wherein the at least one first and second nourishing elements may be the same or different, and further wherein at least one of the first and second nourishing elements has a relative energy state value greater than the pre-existing state a relative energy state value of at least one of the first and second nourishing elements, the greater relative energy state value of at least one of the first and second nourishing elements being sufficient to improve the plant growing in the modified soil, and not Comparison of plants grown in the modified soil.

The present disclosure also relates to an improved plant produced by treating a plant with a composition comprising a first composition comprising at least one organic acid, the organic acid comprising at least one first nourishment element And a second composition comprising at least one photosensitive material, the photosensitive material comprising at least one second nourishing element, the at least one photosensitive material being different from the at least one organic acidic substance, wherein the at least one first The second nourishing elements may be the same or different, and further wherein at least one of the first and second nourishing elements has a relative energy state value greater than a relative energy of at least one of the first and second nourishing elements in the pre-existing state The state value, the greater relative energy state value of at least one of the first and second nourishing elements is sufficient to improve the plant grown by treatment with the composition, as compared to a plant not treated with the composition.

The present disclosure also relates to an improved plant produced by growing the plant in an improved soil treated with an effective amount of a composition comprising a first composition comprising at least one organic acid. And a second composition comprising at least one photosensitive material, wherein at least one of the first composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitive material and the at least one An organic acid substance is different, and further wherein the at least one first nourishing element has a relative energy state value greater than a relative energy state value of the at least one first nourishing element in a pre-existing state, the at least one first nourishing element Larger relative energy state values are sufficient to improve the growth of plants grown in the modified soil compared to plants that are not grown in the modified soil.

The present disclosure also relates to an improved plant produced by treating a plant with a composition comprising a first composition comprising at least one organic acid and a second comprising at least one photosensitive material a composition, wherein at least one of the first composition and the second composition comprises at least one first trophic element, wherein the at least one photosensitive material is different from the at least one organic acidic substance, and further wherein the at least one a relative energy state value possessed by a nourishing element is greater than a relative energy state value of the at least one first nourishing element in the pre-existing state, the larger relative energy state value of the at least one first nourishing element being sufficient to improve the composition Treated plants are compared to plants not treated with the composition.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in an improved soil treated with an effective amount of a composition comprising at least one organic acid. a first composition, the organic acidic substance comprising at least one first nourishing element; and a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishing element, the at least one photosensitive The sexual substance is different from the at least one organic acidic substance, wherein the at least one first and second nourishing elements may be the same or different, and further wherein at least one of the first and second nourishing elements has a relative energy state value greater than the a relative energy state value of at least one of the first and second nourishing elements in a pre-existing state, the greater relative energy state value of at least one of the first and second nourishing elements being sufficient to grow in the modified soil Plants produce improved seeds and/or improved plant products, and plants that are not grown in the modified soil Compared.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant treated with an effective amount of a composition comprising a first composition comprising at least one organic acidic material, The organic acid substance comprises at least one first nourishing element; and a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishing element, the at least one photosensitive substance and the at least one organic acid Different in substance, wherein the at least one first and second nourishing elements may be the same or different, and further wherein at least one of the first and second nourishing elements possesses a relative energy state value greater than the first state of the pre-existing state a relative energy state value of at least one of the second nourishing elements, the greater relative energy state value of at least one of the first and second nourishing elements being sufficient for the treated plant to produce improved seeds and/or improved plants The product is compared to plants that are not produced from this treatment.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in an improved soil treated with an effective amount of a composition comprising at least one organic acid. a first composition and a second composition comprising at least one photosensitive material, wherein at least one of the first composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitive The sexual substance is different from the at least one organic acidic substance, and further wherein the at least one first nourishing element has a relative energy state value greater than a relative energy state value of the at least one first nourishing element in the pre-existing state, the at least one The greater relative energy state value of the first nourishing element is sufficient for growth in the modified soil and the plants irrigated by the brine produce improved seeds and/or improved plant products, and are not grown in the modified soil. Comparison of plants.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant treated with an effective amount of a composition comprising a first composition comprising at least one organic acidic substance and a a second composition comprising at least one photosensitive material, wherein at least one of the first composition and the second composition comprises at least one first trophic element, wherein the at least one photosensitive material and the at least one organic acid The substance is different, and further wherein the at least one first nourishing element has a relative energy state value greater than a relative energy state value of the at least one first nourishing element in a pre-existing state, the larger relative of the at least one first nourishing element The energy state value is sufficient for the plants treated with the composition and all or part of the saline irrigated plants to produce improved seeds and/or improved plant products, as compared to plants that are not so treated.

The present disclosure also relates to a composition comprising a first composition comprising at least one organic acidic material, the organic acidic material comprising at least one first nourishing element; and a second composition comprising at least one photosensitive material The photosensitive substance comprises at least one second nourishing element, wherein the at least one photosensitive substance is different from the at least one organic acidic substance, further wherein the at least one first and second nourishing elements may be the same or different, and even further The relative energy state value possessed by at least one of the first and second nourishing elements is greater than a relative energy state value of at least one of the first and second nourishing elements in a pre-existing state, the first and second nourishing elements At least one of the greater relative energy state values is sufficient to enable the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated with saline to support plant growth, and when the soil is not combined with the composition Compare.

The composition may further comprise a third composition comprising at least one organic base material, optionally comprising at least one third nourishing element, the at least one third nourishing element being the same as the at least one first and second nourishing elements Or different, and the at least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance. The relative energy state value possessed by the at least one third nourishing element of the organic base material is greater than the relative energy state value of the at least one third nourishing element in the pre-existing state, the greater relative energy state of the at least one third nourishing element A sufficient value, either alone or in combination with at least one of the first and second nourishing elements, to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, and the soil is not The compositions were compared when combined. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to a composition comprising at least one photosensitive material, the photosensitive material comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than the at least one nourishing element in the pre-existing state The relative energy state value, the larger relative energy state value is sufficient to enable the composition to improve soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated by saline.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising a first composition comprising at least one organic acidic material, the organic acidic material comprising at least one a trophic element; and a second composition comprising at least one photosensitive material, the photosensitive material comprising at least one second nourishing element, wherein the at least one photosensitive substance is different from the at least one organic acidic substance, further wherein The at least one first and second nourishing elements may be the same or different, and even further wherein at least one of the first and second nourishing elements possesses a relative energy state value greater than the first and second nourishing elements in the pre-existing state a relative energy state value of at least one of the first and second nourishing elements, the greater relative energy state value of the first and second nourishing elements being sufficient and lasting for a sufficient period of time to improve the soil (when combined with the composition) all or part Irrigation with saline is used to support plant growth, as compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising a first composition comprising at least one organic acidic substance, the organic acidic substance comprising at least one first nourishing element; and one comprising at least one a second composition of the photosensitive material, the photosensitive material comprising at least one second nourishing element, wherein the at least one photosensitive substance is different from the at least one organic acidic substance, further wherein the at least one first and second nourishing elements The same or different, and even further wherein the relative energy state value possessed by at least one of the first and second nourishing elements is greater than a relative energy state value of the at least one of the first and second nourishing elements in the pre-existing state, The greater relative energy state value of at least one of the first and second nourishing elements is sufficient to enable the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated with saline to support plant growth, Compare with the soil when not combined with the composition.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one photosensitizing substance comprising at least one nourishing element, wherein the at least one nourishing element has The relative energy state value is greater than a relative energy state value of the at least one nourishing element in the pre-existing state, the larger relative energy state value being sufficient to improve the soil (when combined with the composition) to support plant growth, The soil is good when it is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising at least one photosensitive material comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than the pre-existing a relative energy state value of at least one of the nourishing elements of the state, the larger relative energy state value being sufficient to enable the composition to improve the soil (when combined with the composition) to support plant growth, which is not This composition is good when combined.

The present disclosure also relates to an improved soil comprising at least one nourishing element having a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, the larger relative energy state A value is sufficient to improve the soil to support plant growth, which is better than soil that does not possess the larger relative energy state value.

The present disclosure also relates to an improved soil having a higher energy than the soil in a pre-existing state, the higher energy being sufficient for the improved soil to support plant growth, which is better than soil that does not possess the higher energy. . For example, the higher energy can result from treating the soil with the composition disclosed herein (i.e., a chemical tool that has absorbed energy). The higher energy can be measured, for example, as disclosed herein, for a higher relative energy state value of the nutrient or a corrected energy spectrum of the soil.

The present disclosure also relates to a composition comprising at least one photosensitive material, the photosensitive material comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than the at least one nourishing element in the pre-existing state Relative to the energy state value, the larger relative energy state value is sufficient to enable the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, and the soil is not The compositions were compared when combined. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to a composition comprising at least one organic acidic substance comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state of the at least one nourishing element in the pre-existing state The greater relative energy state value is sufficient to enable the composition to improve soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one photosensitizing substance comprising at least one nourishing element, wherein the at least one nourishing element has The relative energy state value is greater than a relative energy state value of the at least one nourishing element in the pre-existing state, the greater relative energy state value being sufficient to improve the soil (when combined with the composition) is fully or partially irrigated with saline The ability to support plant growth is compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising at least one photosensitive material, comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative value of the at least one nourishing element in the pre-existing state An energy state value that improves the ability of the soil to support plant growth by saline irrigation, compared to the soil that does not comprise at least one photosensitizing substance comprising at least one nourishing element, wherein the at least A nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one organic acidic substance comprising at least one nourishing element, wherein the at least one nourishing element has The relative energy state value is greater than a relative energy state value of the at least one nourishing element in the pre-existing state, the larger relative energy state value being sufficient to improve the treated soil to support plant growth, which is not treated as such Good time.

The present disclosure also relates to an improved soil comprising at least one organic acidic substance comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative value of the at least one nourishing element in the pre-existing state An energy state value sufficient to improve the soil to support plant growth, which is better than the soil when the at least one organic acid (which contains at least one nourishing element) is not included, wherein the at least one The nourishing element has a relative energy state value that is greater than a relative energy state value of the at least one nourishing element in the pre-existing state.

The present disclosure also relates to an improved soil made, for example, by treating soil with the compositions disclosed herein; with respect to a modified composition comprising the compositions disclosed herein or included in the compositions disclosed herein. a modified soil of the form; an improved plant grown in the soil modified as disclosed herein or treated with the compositions disclosed herein; and as for example from the soil modified in the context disclosed herein Improved seeds and/or improved plant products produced by plants grown or treated with the compositions disclosed herein. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to a composition comprising at least one organic acidic substance comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state of the at least one nourishing element in the pre-existing state The greater relative energy state value is sufficient to enable the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, and the soil when not associated with the composition Compare when combined. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% Agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, relative to the total of the first composition Weight of the weight; the second composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1 % zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, based on the total weight of the second composition, and the second composition further comprises about 1.5 ppm of 5-amino groups. 4-pentanone acid ("5-ALA"), which is commercially available from Beijing Yushenghong Chemical Co., Ltd., relative to the second group The total weight of the product; and the third composition comprises stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein the first, second and third nourishment At least one of the elements has a relative energy state value greater than a relative energy state value of the at least one of the first, second, and third nourishing elements in a pre-existing state, the at least one of the first, second, and third nourishing elements A larger relative energy state value (alone or in combination) is sufficient to enable the composition to improve soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil which is produced, for example, by treating the soil with the composition; and with regard to the improved plant and/or modified seed, for example by growth in the modified soil or This composition is produced. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

For example, the present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one organic acidic substance comprising at least one nourishing element, wherein the at least one nourishing element Having a relative energy state value greater than a relative energy state value of the at least one trophozoic element in a pre-existing state, the greater relative energy state value being sufficient to modify the soil (when combined with the composition) all or part of the brine Irrigation is used to support plant growth, as compared to when the soil is not combined with the composition.

In a further embodiment, the present disclosure is also directed to an improved soil comprising at least one organic acidic material comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than the pre-existing state a relative energy state value of a nourishing element that improves the ability of the soil (when combined with the composition) to support plant growth by saline irrigation, and which does not comprise at least one organic acid species ( A soil comparison comprising at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of at least one of the nourishing elements in a pre-existing state.

With regard to still further embodiments, the present disclosure is also directed to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element. a second composition comprising about 15% of at least one second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, by weight relative to the total weight of the composition; Wherein the first composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, About 0.5% copper sulfate and about 1% ferrous sulfate, based on the total weight of the first composition; the second composition comprises about 70% stalk powder, about 10% phosphate ore particles, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, relative to the second composition The weight of the total weight, and the second composition further contains about 1.5 ppm of 5-ALA, relative The total weight of the second composition; and the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the first, the first At least one of the second and third nourishing elements possesses a relative energy state value greater than a relative energy state value of at least one of the first, second, and third nourishing elements in a pre-existing state, the first, second, and The larger relative energy state values (alone or in combination) of at least one of the three nourishing elements are sufficient to improve the soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising at least one nourishing element, and stalk powder, phosphate rock granules, agricultural grade amino acids, corn or potato starch, manganese sulfate, zinc sulfate, copper sulfate, and ferrous sulfate, and 5-ALA, and the at least one nourishing element possesses a relative energy state value greater than a relative energy state value of at least one nourishing element in a pre-existing state, the larger relative energy state value of the at least one nourishing element being sufficient and lasting for a period of time Sufficient time to improve the soil to support plant growth, which is better than when the soil does not contain at least one nourishing element that has a relative energy state value greater than the relative energy state value of at least one of the nourishing elements in a pre-existing state.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% Agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, relative to the total of the first composition Weight of the weight; the second composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1 % zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, based on the total weight of the second composition, and the second composition further comprises about 1.5 ppm of 5-ALA, Relative to the total weight of the second composition; and the third composition comprises stalk powder, and the at least one of the The second and third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than the first and second in the pre-existing state And a relative energy state value of at least one of the third nourishing elements, the larger relative energy state values (alone or in combination) of the at least one of the first, second, and third nourishing elements being sufficient to enable the composition to improve the soil ( The ability to irrigate all or part of the saline to support plant growth when combined with the composition is compared to when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% Agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% molybdic acid Ammonium and about 0.4% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amine Base acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second composition further comprises about 2 ppm of 5-ALA to The weight of the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the first And at least one of the second and third nourishing elements has a relative energy state value greater than a relative energy state value of the at least one of the first, second, and third nourishing elements in the pre-existing state, the first and second And a larger relative energy state value (alone or in combination) of at least one of the third nourishing elements is sufficient to enable the composition to improve soil (when combined with the composition) to support plant growth, which is not It is good when the composition is combined. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least one a second composition of di nourishing elements and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises About 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1 % ferrous sulfate, based on the total weight of the first composition; the second composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, About 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, based on the total weight of the second composition, and The second composition further comprises about 1.5 ppm of 5-ALA relative to the total weight of the second composition; And the third composition comprises a stalk powder, and wherein the at least one first, second and third nourishing elements are the same or different, and further wherein at least one of the first, second and third nourishing elements possesses a relative energy state value greater than a relative energy state value of at least one of the first, second, and third nourishing elements in a pre-existing state, a larger relative energy of at least one of the first, second, and third nourishing elements The state values (alone or in combination) are sufficient to modify the soil (when combined with the composition) to be fully or partially irrigated with saline to support plant growth, as compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, About 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% ammonium molybdate, and about 0.4% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% Copper sulphate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, relative to the total weight of the second composition The weight, and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein The at least one first, second, and third nourishing elements may be the same or different, and further wherein at least one of the first, second, and third nourishing elements possesses a relative energy state value greater than the first pre-existing state a relative energy state value of at least one of the second and third nourishing elements, and a larger relative energy state value (alone or in combination) of at least one of the first, second, and third nourishing elements is sufficient to improve the soil (when When combined with the composition) supports plant growth which is better than when the soil is not combined with the composition.

The present disclosure also relates to an improved plant produced by treating the plant with an improved soil treated with an effective amount of a composition comprising about 15% of the first comprising at least one first nourishing element a secondary composition, about 15% of a second composition comprising at least one second nourishing element, and a third composition of about 70% selectively comprising at least one third nourishing element, relative to the total weight of the composition By weight; wherein the first composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% Zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, based on the total weight of the first composition; the second composition comprises about 70% stalk powder, about 10% phosphate rock Granules, about 12% agricultural grade amino acids, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, relative to the second The weight of the total weight of the secondary composition, and the second composition further comprises about 1.5 ppm of 5-ALA, Relative to the total weight of the second composition; and the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the first At least one of the second and third nourishing elements possesses a relative energy state value greater than a relative energy state value of at least one of the first, second, and third nourishing elements in a pre-existing state, the first and second The greater relative energy state value (alone or in combination) of at least one of the third nourishing elements is sufficient to enable the composition to improve the soil (when combined with the composition) such that it can be produced in whole or in part by salt water irrigation The ability of the improved plant is compared to plants that are not so produced.

The present disclosure also relates to an improved plant produced by treating the plant with a modified soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element, About 15% of the second composition comprising at least one second nourishing element and about 70% of the third composition optionally comprising at least one third nourishing element, by weight relative to the total weight of the composition; The first composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulphate, about 1% zinc sulphate, about 0.5% copper sulphate and about 1% ferrous sulfate, based on the total weight of the first composition; the second composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12 % agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, relative to the second composition The weight of the total weight, and the second composition further comprises about 1.5 ppm of 5-ALA, relative to the first a total weight of the secondary composition; and the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the first, second, and At least one of the three nourishing elements possesses a relative energy state value greater than a relative energy state value of at least one of the first, second, and third nourishing elements in a pre-existing state, the first, second, and third nourishing elements At least one of the greater relative energy state values (alone or in combination) is sufficient to improve the ability of the soil (when combined with the composition) to enable it to be fully or partially irrigated with saline to produce the improved plant, and Plants that are not so produced are compared.

The present disclosure also relates to an improved plant produced by growing the plant in an improved soil treated with an effective amount of a composition comprising about 15% of a first soil containing at least one first nourishing element. a primary composition, about 15% of a second composition comprising at least one second nourishing element, and a third composition of about 70% selectively comprising at least one third nourishing element, relative to the total weight of the composition The weight of the first composition comprising about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1 % manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% ammonium molybdate, and about 0.4% borax, by weight relative to the total weight of the first composition. Wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate , about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate and about 0.8% borax, in phase The weight of the total weight of the second composition, and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; The tertiary composition comprises a stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein the relative energy possessed by at least one of the first, second and third nourishing elements a relative energy state value of the at least one of the first, second, and third nourishing elements in the pre-existing state, and a greater relative energy state value of the at least one of the first, second, and third nourishing elements ( Individually or in combination) is sufficient to produce the improved plant as compared to a plant that is not so produced.

The present disclosure also relates to an improved plant produced by growing the plant in an improved soil comprising a composition comprising about 15% of the first composition comprising at least one first nourishing element a second composition comprising about 15% of at least one second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, by weight relative to the total weight of the composition; Wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, About 1% zinc sulfate, about 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% ammonium molybdate, and about 0.4% borax, based on the total weight of the first composition; The secondary composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% Zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, relative to the second The weight of the total weight of the composition, and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises The stalk powder, and the at least one first, second and third nourishing elements thereof may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than the stalk a relative energy state value of at least one of the first, second, and third nourishing elements in the pre-existing state, the large relative energy state value (alone or in combination) of at least one of the first, second, and third nourishing elements is sufficient The soil is modified (when combined with the composition) to produce the improved plant, as compared to plants that are not so produced.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in an improved soil treated with an effective amount of a composition comprising about 15% comprising at least one a first composition of a nourishing element, a second composition comprising about 15% comprising at least one second nourishing element, and a third composition comprising about 70% selectively comprising at least one third nourishing element, relative to the The weight of the total weight of the composition; wherein the first composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% Manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, based on the total weight of the first composition; the second composition comprises about 70% stalk powder About 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate. Based on the weight of the total weight of the second composition, and the second composition Containing about 1.5 ppm of 5-ALA, relative to the total weight of the second composition; and the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or Different, and further wherein at least one of the first, second, and third nourishing elements possesses a relative energy state value greater than a relative energy state of at least one of the first, second, and third nourishing elements in a pre-existing state a greater relative energy state value (alone or in combination) of at least one of the first, second and third trophic elements sufficient for the treated plant to be irrigated with saline and to produce improved seeds and/or improved Plant products are compared to seeds and/or plant products that are not so produced.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in a modified soil comprising a composition comprising about 15% comprising at least one first nourishing element. a first composition, about 15% of a second composition comprising at least one second nourishing element, and a third composition of about 70% selectively comprising at least one third nourishing element, relative to the total composition of the composition Weight of the weight; wherein the first composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, based on the total weight of the first composition; the second composition comprises about 70% stalk powder, about 10% Phosphate ore particles, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, relative to the The weight of the total weight of the second composition, and the second composition further comprises about 1.5 ppm 5-ALA, relative to the total weight of the second composition; and the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein At least one of the first, second, and third nourishing elements possesses a relative energy state value greater than a relative energy state value of at least one of the first, second, and third nourishing elements in a pre-existing state, the first And a greater relative energy state value (alone or in combination) of at least one of the second and third nourishing elements is sufficient for the treated plant to be irrigated with saline and to produce improved seeds and/or improved plant products, and When not so produced seed and / or plant products are compared.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in an improved soil treated with an effective amount of a composition comprising about 15% comprising at least one a first composition of a nourishing element, a second composition comprising about 15% comprising at least one second nourishing element, and a third composition comprising about 70% selectively comprising at least one third nourishing element, relative to the The weight of the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% a water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% ammonium molybdate, and about 0.4% borax, relative to the first composition. The weight of the total weight; wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, About 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate and 0.8% borax, based on the total weight of the second composition, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total weight of the second composition. a weight; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein at least the first, second, and third nourishing elements are a relative energy state value of at least one of the first, second, and third nourishing elements in the pre-existing state, and at least one of the first, second, and third nourishing elements The large relative energy state values (alone or in combination) are sufficient for the treated plant to produce improved seeds and/or improved plant products, as compared to seeds and/or plant products when not so produced.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in a modified soil comprising a composition comprising about 15% comprising at least one first nourishing element. a first composition, about 15% of a second composition comprising at least one second nourishing element, and a third composition of about 70% selectively comprising at least one third nourishing element, relative to the total composition of the composition Weight of the weight; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% ammonium molybdate, and about 0.4% borax, by weight relative to the total weight of the first composition. Wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% sulfuric acid Manganese, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, The second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition, by weight relative to the total weight of the second composition; The third composition comprises a stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein the relative possession of at least one of the first, second and third nourishing elements The energy state value is greater than a relative energy state value of at least one of the first, second, and third nourishing elements in the pre-existing state, and a greater relative energy state value of at least one of the first, second, and third nourishing elements (alone or in combination) is sufficient for the treated plant to produce improved seeds and/or improved plant products, as compared to seeds and/or plant products when not so produced.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% Agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% molybdic acid Ammonium and about 0.4% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amine Base acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second composition further comprises about 2 ppm of 5-ALA to The weight of the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the first And at least one of the second and third nourishing elements has a relative energy state value greater than a relative energy state value of the at least one of the first, second, and third nourishing elements in the pre-existing state, the first and second And a larger relative energy state value (alone or in combination) of at least one of the third nourishing elements is sufficient to enable the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth. And compared to the soil when not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 12% phosphate rock granules, about 15% Agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax , by weight of the total weight of the first composition; wherein the second composition comprises 57% stalk powder, about 13% phosphate rock granules, about 16% agricultural grade amino acid, about 7% corn Or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, and about 0.2% ammonium molybdate and about 0.8% borax, relative to the second composition. The total weight of the weight, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total of the second composition a weight of the amount; wherein the third composition comprises stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein the first, second and third nourishing elements At least one of the relative energy state values possessed by the at least one of the relative energy state values of the at least one of the first, second, and third nourishing elements in the pre-existing state, at least one of the first, second, and third nourishing elements The larger relative energy state values (alone or in combination) are sufficient to enable the composition to improve soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, About 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% ammonium molybdate, and about 0.4% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% Copper sulphate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, relative to the total weight of the second composition The weight, and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein The at least one first, second, and third nourishing elements may be the same or different, and further wherein at least one of the first, second, and third nourishing elements possesses a relative energy state value greater than the first pre-existing state a relative energy state value of at least one of the second and third nourishing elements, and a larger relative energy state value (alone or in combination) of at least one of the first, second, and third nourishing elements is sufficient to improve the soil (when When combined with the composition, all or part of the irrigation is supported by saline to support plant growth, as compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 12% phosphate rock granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate, About 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises 57% stalk powder, about 13 % phosphate ore granules, about 16% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, and about 0.2% Ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second time The composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and the at least one of the first and second The third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than the first, second and third nourishing elements in the pre-existing state a relative energy state value of at least one of the greater relative energy state values (alone or in combination) of at least one of the first, second, and third nourishing elements sufficient to improve the soil (when combined with the composition) Plant growth, which is better than when the soil is not combined with the composition.

The present disclosure also relates to an improved plant produced by growing the plant in an improved soil treated with an effective amount of a composition comprising about 15% of a first soil containing at least one first nourishing element. a primary composition, about 15% of a second composition comprising at least one second nourishing element, and a third composition of about 70% selectively comprising at least one third nourishing element, relative to the total weight of the composition The weight of the first composition comprising about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1 % manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% ammonium molybdate, and about 0.4% borax, by weight relative to the total weight of the first composition. Wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate , about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate and about 0.8% borax, in phase The weight of the total weight of the second composition, and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; The tertiary composition comprises a stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein the relative energy possessed by at least one of the first, second and third nourishing elements a relative energy state value of the at least one of the first, second, and third nourishing elements in the pre-existing state, and a greater relative energy state value of the at least one of the first, second, and third nourishing elements ( Individually or in combination) is sufficient to improve plants grown in the modified soil and all or part of which are irrigated by saline, as compared to plants that are not grown in the modified soil.

The present disclosure also relates to an improved plant produced by growing the plant in an improved soil treated with an effective amount of a composition comprising about 15% of a first soil containing at least one first nourishing element. a primary composition, about 15% of a second composition comprising at least one second nourishing element, and a third composition of about 70% selectively comprising at least one third nourishing element, relative to the total weight of the composition The weight of the first composition comprising about 60% stalk powder, about 12% phosphate rock granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5. % zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second time The composition comprises 57% stalk powder, about 13% phosphate rock granules, about 16% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate, About 2% ferrous sulfate and about 0.2% ammonium molybdate and about 0.8% borax, relative to the second composition The weight of the weight, and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and Wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than the pre-existing state a relative energy state value of at least one of the first, second, and third nourishing elements, and a larger relative energy state value (alone or in combination) of at least one of the first, second, and third nourishing elements is sufficient to improve Plants grown in the modified soil are compared to plants that are not grown in the modified soil.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in an improved soil treated with an effective amount of a composition comprising about 15% comprising at least one a first composition of a nourishing element, a second composition comprising about 15% comprising at least one second nourishing element, and a third composition comprising about 70% selectively comprising at least one third nourishing element, relative to the The weight of the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% a water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% ammonium molybdate, and about 0.4% borax, relative to the first composition. The weight of the total weight; wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, About 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate and 0.8% borax, based on the total weight of the second composition, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total weight of the second composition. a weight; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein at least the first, second, and third nourishing elements are a relative energy state value of at least one of the first, second, and third nourishing elements in the pre-existing state, and at least one of the first, second, and third nourishing elements Large relative energy state values (alone or in combination) are sufficient for the grown plants to produce improved seeds and/or improved plant products, as compared to seeds and/or plant products when not so produced.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in a modified soil comprising a composition comprising about 15% comprising at least one first nourishing element. a first composition, about 15% of a second composition comprising at least one second nourishing element, and a third composition of about 70% selectively comprising at least one third nourishing element, relative to the total composition of the composition Weight of the weight; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% ammonium molybdate, and about 0.4% borax, by weight relative to the total weight of the first composition. Wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% sulfuric acid Manganese, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, The second composition further comprises about 2 ppm of 5-ALA by weight relative to the total weight of the second composition, based on the total weight of the second composition; The third composition comprises a stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein the relative possession of at least one of the first, second and third nourishing elements The energy state value is greater than a relative energy state value of at least one of the first, second, and third nourishing elements in the pre-existing state, and a greater relative energy state value of at least one of the first, second, and third nourishing elements (alone or in combination) is sufficient for the grown plants to produce improved seeds and/or improved plant products, as compared to seeds and/or plant products when not so produced.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in an improved soil treated with an effective amount of a composition comprising about 15% comprising at least one a first composition of a nourishing element, a second composition comprising about 15% comprising at least one second nourishing element, and a third composition comprising about 70% selectively comprising at least one third nourishing element, relative to the The weight of the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 12% phosphate rock granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% Manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; Wherein the second composition comprises 57% stalk powder, about 13% phosphate rock granules, about 16% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulfate, about 2% ferrous sulfate and about 0.2% ammonium molybdate and about 0.8% borax, relative to the The weight of the total weight of the secondary composition, and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition The material comprises a stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than a relative energy state value of at least one of the first, second, and third nourishing elements in a pre-existing state, a larger relative energy state value of at least one of the first, second, and third nourishing elements (alone or in combination Sufficient to allow the grown plants to produce improved seeds and/or improved plant products, as compared to seeds and/or plant products when not so produced.

The present disclosure also relates to an improved seed and/or improved plant product produced from a plant grown in a modified soil comprising a composition comprising about 15% comprising at least one first nourishing element. a first composition, about 15% of a second composition comprising at least one second nourishing element, and a third composition of about 70% selectively comprising at least one third nourishing element, relative to the total composition of the composition Weight of the weight; wherein the first composition comprises about 60% stalk powder, about 12% phosphate rock granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second The secondary composition comprises 57% stalk powder, about 13% phosphate rock granules, about 16% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate. , about 2% ferrous sulfate and about 0.2% ammonium molybdate and about 0.8% borax, relative to the second composition The weight of the total weight, and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder And the at least one of the first, second and third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements possesses a relative energy state value greater than the pre-existing a relative energy state value of at least one of the first, second, and third nourishing elements of the state, the larger relative energy state value (alone or in combination) of at least one of the first, second, and third nourishing elements is sufficient The grown plants produce improved seeds and/or improved plant products that are compared to seeds and/or plant products when not so produced.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 12% phosphate rock granules, about 15% Agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax , by weight of the total weight of the first composition; wherein the second composition comprises about 57% stalk powder, about 13% phosphate rock granules, about 16% agricultural grade amino acid, about 7% Corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, and about 0.2% ammonium molybdate and about 0.8% borax, relative to the second composition The weight of the total weight of the article, and the second composition further comprises about 2 ppm of 5-ALA relative to the second composition a weight of the weight; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the first, second, and third nourishing elements At least one of the relative energy state values possessed by the at least one of the relative energy state values of the at least one of the first, second, and third nourishing elements in the pre-existing state, at least one of the first, second, and third nourishing elements The greater relative energy state values (alone or in combination) are sufficient to enable the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated with saline to support plant growth, and the soil is not The compositions were compared when combined. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% Agricultural grade amino acid, about 5% fatty acid, about 5% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate And about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 9% phosphate rock granules, about 15% agricultural grade amine base Acid, about 5% fatty acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, and about 2% ferrous sulfate, relative to the second composition The weight of the total weight, and the second composition further comprises about 1.5 ppm of 5-ALA, relative to the total weight of the second composition. a weight of the amount; wherein the third composition comprises stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein the first, second and third nourishing elements At least one of the relative energy state values possessed by the at least one of the relative energy state values of the at least one of the first, second, and third nourishing elements in the pre-existing state, at least one of the first, second, and third nourishing elements The larger relative energy state values (alone or in combination) are sufficient to enable the composition to improve soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

For example, the present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% a second composition comprising at least one second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first The secondary composition comprises about 60% stalk powder, about 12% phosphate rock granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% sulphuric acid. Copper, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 57% stalk powder , about 13% phosphate rock granules, about 16% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate and About 0.2% ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and The second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and the at least one of the first, The second and third nourishing elements may be the same or different, and further wherein at least one of the first, second, and third nourishing elements has a relative energy state value greater than the first, second, and first in the pre-existing state a relative energy state value of at least one of the three nourishing elements, a larger relative energy state value (alone or in combination) of at least one of the first, second, and third nourishing elements sufficient to improve the soil to be fully or partially irrigated by the saline Support plant growth compared to soils that are not treated as such.

With regard to further embodiments, the present disclosure is also directed to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, About 15% of the second composition comprising at least one second nourishing element and about 70% of the third composition optionally comprising at least one third nourishing element, by weight relative to the total weight of the composition; The first composition comprises about 60% stalk powder, about 8% phosphate rock granules, about 15% agricultural grade amino acid, about 5% fatty acid, about 5% corn or potato starch, about 1.5% manganese sulfate, about 1.5. % zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second time The composition comprises about 60% stalk powder, about 9% phosphate rock granules, about 15% agricultural grade amino acid, about 5% fatty acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, About 1% copper sulfate and about 2% ferrous sulfate, based on the total weight of the second composition And the second composition further comprises about 1.5 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least a first, second, and third nourishing elements may be the same or different, and further wherein at least one of the first, second, and third nourishing elements possesses a relative energy state value greater than the first, pre-existing state a relative energy state value of at least one of the second and third nourishing elements, the greater relative energy state value (alone or in combination) of at least one of the first, second, and third nourishing elements sufficient to improve the soil to support plant growth It is better than soil that is not treated as such.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% Agricultural grade amino acid, about 5% fatty acid, about 5% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate And about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 9% phosphate rock granules, about 15% agricultural grade amine base Acid, about 5% fatty acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, and about 2% ferrous sulfate, relative to the second composition The weight of the total weight, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total weight of the second composition. a weight of the third composition comprising a stalk powder, wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein the first, second and third nourishing elements Having at least one relative energy state value greater than a relative energy state value of at least one of the first, second, and third nourishing elements in a pre-existing state, at least one of the first, second, and third nourishing elements Larger relative energy state values (alone or in combination) are sufficient to enable the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated with saline to support plant growth, and the soil does not The composition is compared when combined. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% Agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax , by weight of the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% Corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, relative to the second composition The weight of the total weight of the article, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total of the second composition. a weight of the weight; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the first, second, and third nourishing elements At least one of the relative energy state values possessed by the at least one of the relative energy state values of the at least one of the first, second, and third nourishing elements in the pre-existing state, at least one of the first, second, and third nourishing elements The larger relative energy state values (alone or in combination) are sufficient to enable the composition to improve soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 8% phosphate rock granules, about 15% agricultural grade amino acid, about 5% fatty acid, about 5% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60 % stalk powder, about 9% phosphate ore granules, about 15% agricultural grade amino acid, about 5% fatty acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate And about 2% ferrous sulfate, based on the total weight of the second composition, and the second composition Further comprising about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one of the first, second, and The three nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than the first, second and third nourishing elements in the pre-existing state a relative energy state value of at least one of the greater relative energy state values (alone or in combination) of at least one of the first, second, and third nourishing elements sufficient to improve the soil (when combined with the composition) The irrigation is supported, in part, by saline irrigation, as compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate, About 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2 % ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second time The composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and the at least one of the first and second The third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than the first, second and third nourishing elements in the pre-existing state a relative energy state value of at least one of the greater relative energy state values (alone or in combination) of at least one of the first, second, and third nourishing elements sufficient to improve the soil (when combined with the composition) Plant growth, which is better than when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% Agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax , by weight of the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% Corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, relative to the second composition The weight of the total weight of the object, and the second composition further comprises about 1.5 ppm of 5-ALA relative to the second composition a weight of the weight; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the first, second, and third nourishing elements At least one of the relative energy state values possessed by the at least one of the relative energy state values of the at least one of the first, second, and third nourishing elements in the pre-existing state, at least one of the first, second, and third nourishing elements The greater relative energy state values (alone or in combination) are sufficient to enable the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated with saline to support plant growth, and the soil is not The compositions were compared when combined. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 17% Agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5% ammonium molybdate and about 0.5% borax , by weight of the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 13% phosphate rock granules, about 15% agricultural grade amino acid, about 6% Corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5% ammonium molybdate, and about 0.5% borax, relative to the second composition The weight of the total weight of the article, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total of the second composition. a weight of the amount; wherein the third composition comprises stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein the first, second and third nourishing elements At least one of the relative energy state values possessed by the at least one of the relative energy state values of the at least one of the first, second, and third nourishing elements in the pre-existing state, at least one of the first, second, and third nourishing elements The larger relative energy state values (alone or in combination) are sufficient to enable the composition to improve soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate, About 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2 % ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second time The composition further comprises about 1.5 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and the at least one of the first and second The third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than the first, second and third nourishing elements in the pre-existing state a relative energy state value of at least one of the plurality, wherein the greater relative energy state values (alone or in combination) of at least one of the first, second, and third nourishing elements are sufficient to improve the soil (when combined with the composition) All or part of the irrigation is supported by saline to support plant growth, as compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2 % ammonium molybdate and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% Agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax , the second composition further comprises about 1.5 ppm of 5-ALA by weight relative to the total weight of the second composition Based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein At least one of the first, second, and third nourishing elements possesses a relative energy state value greater than a relative energy state value of at least one of the first, second, and third nourishing elements in a pre-existing state, the first And a greater relative energy state value (alone or in combination) of at least one of the second and third nourishing elements is sufficient to enable the composition to improve the soil (when combined with the composition) all or part of the saline irrigation The ability to support plant growth is compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 17% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate, About 2% ferrous sulfate, about 0.5% ammonium molybdate, and about 0.5% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 13% phosphate rock granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5 % ammonium molybdate and about 0.5% borax, based on the total weight of the second composition, and the second group The composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and the at least one of the first and second The third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than the first, second and third nourishing elements in the pre-existing state a relative energy state value of at least one of the plurality, the greater relative energy state values (alone or in combination) of the at least one of the first, second, and third nourishing elements are sufficient and last for a sufficient period of time to improve the soil (when When the substance is combined, it supports plant growth, which is better than when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 17% Agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5% ammonium molybdate and about 0.5% borax , by weight of the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 13% phosphate rock granules, about 15% agricultural grade amino acid, about 6% Corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5% ammonium molybdate, and about 0.5% borax, relative to the second composition The weight of the total weight of the article, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total of the second composition. a weight of the amount; wherein the third composition comprises stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein the first, second and third nourishing elements At least one of the relative energy state values possessed by the at least one of the relative energy state values of the at least one of the first, second, and third nourishing elements in the pre-existing state, at least one of the first, second, and third nourishing elements The greater relative energy state values (alone or in combination) are sufficient to enable the composition to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated with saline to support plant growth, and the soil is not The compositions were compared when combined. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 17% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate, About 2% ferrous sulfate, about 0.5% ammonium molybdate, and about 0.5% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 13% phosphate rock granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5 % ammonium molybdate and about 0.5% borax, based on the total weight of the second composition, and the second group The composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and the at least one of the first and second The third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than the first, second and third nourishing elements in the pre-existing state a relative energy state value of at least one of the plurality, wherein the greater relative energy state values (alone or in combination) of at least one of the first, second, and third nourishing elements are sufficient to improve the soil (when combined with the composition) All or part of the irrigation is supported by saline to support plant growth, as compared to when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more positive than an energy spectrum of the pre-existing composition, the corrected energy spectrum being sufficient to improve the composition The soil (when combined with the composition) supports plant growth which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more positive than an energy spectrum of the pre-existing composition. The composition is effective to improve the soil to support plant growth, which is better than when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising at least one nourishing element, wherein the soil has an energy spectrum that is more positive than the energy spectrum of the pre-existing soil, and wherein the soil supports plant growth, which is The soil in the state of existence is good.

The present disclosure also relates to a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more positive than an energy spectrum of the pre-existing composition, the corrected energy spectrum being sufficient and lasting for a sufficient period of time to The composition is capable of improving virgin soil (when combined with the composition) to support plant growth, which is better than when the virgin soil is not bound to the composition, wherein the virgin soil does not support plant growth prior to binding to the composition . The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved virgin soil treated with a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more positive than an energy spectrum of the pre-existing composition, the corrected energy spectrum is sufficient And for a period of time sufficient to allow the composition to improve the virgin soil (when combined with the composition) to support plant growth, which is better than when the virgin soil is not combined with the composition, wherein the virgin soil is associated with the composition Plant growth cannot be supported before the substance is combined.

The present disclosure also relates to an improved virgin soil comprising a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more positive than an energy spectrum of the pre-existing composition, the corrected energy spectrum It is sufficient to improve the virgin soil to support plant growth, which is better than when the virgin soil is not combined with the composition, wherein the virgin soil cannot support plant growth prior to binding to the composition.

The present disclosure also relates to a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more positive than an energy spectrum of the pre-existing composition, the corrected energy spectrum being sufficient to allow the composition to be selected The soil from sand/loamy sand, heavy clay, clay, sandy clay, sandy clay loam, silty clay, silty clay loam and silt loam is converted from sandy loam and loam. A modified soil of clay, clay loam, and loam when the soil is combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more correct than the energy spectrum of the pre-existing composition. The corrected energy spectrum is sufficient for the composition to be selected from sand/loar sand, heavy clay, clay, sandy clay, sandy clay loam, silty clay, silty clay loam and silt The loam soil is converted into a modified soil selected from the group consisting of sandy loam, loamy clay, clay loam and loam when the soil is combined with the composition.

The present disclosure also relates to an improved soil comprising at least one nourishing element, wherein the composition has an energy spectrum that is more positive than an energy spectrum of the pre-existing composition, the composition being effective to be selected from sand/ The soil of loamy sand, heavy clay, clay, sandy clay, sandy clay loam, silty clay, silty clay loam and silt loam is converted into sandy loam, loamy clay and clay loam. And improved soil of loam when the soil is combined with the composition.

The present disclosure also relates to a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, the composition being effective (perhaps (not limited by theory) because Its corrected energy spectrum) converts non-loar soil into loam when the soil is combined with the composition. The present disclosure also relates to a loam that is produced, for example, by treating a soil that is not loam with the composition; and for improved plants and/or passages produced, for example, by growth in the loam or treatment with the composition. Improved seeds. And the loam can be sufficiently modified such that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more correct than the energy spectrum of the pre-existing composition. And the composition converts the soil that is not loam into loam.

The present disclosure also relates to an improved soil having an energy spectrum that is more positive than an energy spectrum of the soil in a pre-existing state, the corrected energy spectrum being sufficient to cause the modified soil to become loam, however, the pre-existing state The soil is not loam.

The present disclosure also relates to a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, the composition being effective (perhaps (not limited by theory) because Its corrected energy spectrum) is to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, as compared to when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more correct than the energy spectrum of the pre-existing composition. The corrected energy spectrum is sufficient to improve the soil in whole or in part by saline irrigation to support plant growth, as compared to soils that are not so treated.

The present disclosure also relates to an improved soil comprising a composition comprising at least one nourishing element, wherein the composition has an energy spectrum that is more positive than an energy spectrum of the pre-existing composition, the composition being effective (perhaps (not limited by theory) because the positive energy spectrum) is to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, compared to when the soil is not combined with the composition. .

The present disclosure also relates to a composition comprising a first composition comprising at least one organic acidic material and a second composition comprising at least one photosensitive material, wherein the first composition and the second composition At least one of the at least one element comprises at least one first trophic element, the at least one photosensitive material being different from the at least one organic acidic substance, and further wherein the energy spectrum possessed by the composition is greater than the energy spectrum of the composition in the pre-existing state Correction, the composition is effective (perhaps (not limited by theory) because of its corrected energy spectrum) improving the ability of the soil (when combined with the composition) to support plant growth, when the soil is not combined with the composition it is good. The composition may further comprise a third composition comprising at least one organic base material, optionally comprising at least one third nourishing element, the at least one third nourishing element being the same as or different from the at least one first nourishing element, And the at least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising a first composition comprising at least one organic acidic material and a composition comprising at least one photosensitive material. a second composition, wherein at least one of the first composition and the second composition comprises at least one first nourishing element, the at least one photosensitive substance is different from the at least one organic acidic substance, and further wherein the composition The energy spectrum possessed by the object is more positive than the energy spectrum of the composition in the pre-existing state, and the composition is effective (perhaps (not limited by theory) because of its corrected energy spectrum) to improve the soil (when combined with the composition) Plant growth is supported which is better than when the soil is not combined with the composition. The composition may further comprise a third composition comprising at least one organic base material, optionally comprising at least one third nourishing element, the at least one third nourishing element being the same as or different from the at least one first nourishing element, And the at least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance.

The present disclosure also relates to a composition comprising a first composition comprising at least one organic acidic material, the organic acidic material comprising at least one first nourishing element; and a second composition comprising at least one photosensitive material The photosensitive substance comprises at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance, wherein the at least one first and second nourishing elements may be the same or different, and further wherein the composition The energy spectrum possessed is more positive than the energy spectrum of the pre-existing composition, which may be effective in improving the soil (when combined with the composition) to support plant growth due to its corrected energy spectrum, which is better than the soil Good when not combined with the composition. The composition may further comprise a third composition comprising at least one organic base material, optionally comprising at least one third nourishing element, the at least one third nourishing element being the same as the at least one first and second nourishing elements Or different, and the at least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising a first composition comprising at least one organic acidic material, the organic acidic material comprising at least one a trophic element; and a second composition comprising at least one photosensitive material, the photosensitive material comprising at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance, wherein the at least one The first and second nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the pre-existing composition, the composition (perhaps because of its corrected energy spectrum) is effective The modified soil (when combined with the composition) supports plant growth which is better than when the soil is not combined with the composition. The composition may further comprise a third composition comprising at least one organic base material, optionally comprising at least one third nourishing element, the at least one third nourishing element being the same as the at least one first and second nourishing elements Or different, and the at least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance.

The present disclosure also relates to an improved soil comprising a composition comprising a first composition comprising at least one organic acidic substance, the organic acidic substance comprising at least one first nourishing element; and one comprising at least one a second composition of the photosensitive material, the photosensitive material comprising at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance, wherein the at least one first and second nourishing elements are the same Or different, and further wherein the composition of the energy spectrum of the composition is more positive than the energy spectrum of the composition in the pre-existing state, the composition (perhaps because of its corrected energy spectrum) is effective to improve the soil (when combined with the composition) Time) supports plant growth which is better than when the soil is not combined with the composition. The composition may further comprise a third composition comprising at least one organic base material, optionally comprising at least one third nourishing element, the at least one third nourishing element being the same as the at least one first and second nourishing elements Or different, and the at least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance.

The present disclosure also relates to a composition comprising a first composition comprising at least one organic acidic material, and a second composition comprising at least one photosensitive material, wherein the first composition and the second time At least one of the compositions comprises at least one first trophic element, wherein the at least one photosensitive material is different from the at least one organic acidic substance, and further wherein the composition has an energy spectrum that is greater than the composition in the pre-existing state The energy spectrum is corrected, and the composition (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil to support plant growth by irrigation with saline when combined with the composition, when the soil is not combined with the composition. Comparison. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The composition may further comprise a third composition comprising at least one organic base material, optionally comprising at least one third nourishing element, the at least one third nourishing element being the same as or different from the at least one first nourishing element, And the at least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising a first composition comprising at least one organic acidic material, and a composition comprising at least one photosensitive material a second composition, wherein at least one of the first composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitive material is different from the at least one organic acidic substance, and further wherein The composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when combined with the composition) by brine irrigation The ability to support plant growth is compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising a first composition comprising at least one organic acidic material, and a second composition comprising at least one photosensitive material, wherein At least one of the first composition and the second composition comprises at least one first nourishing element, wherein the at least one photosensitive material is different from the at least one organic acidic substance, and further wherein the composition has an energy spectral ratio The energy spectrum of the composition in the pre-existing state is corrected, and the composition (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil to support plant growth by irrigation with saline (when combined with the composition), The soil is compared when it is not combined with the composition.

The present disclosure also relates to a composition comprising a first composition comprising at least one organic acidic material, the organic acidic material comprising at least one first nourishing element; and a second composition comprising at least one photosensitive material The photosensitive substance comprises at least one second nourishing element, wherein the at least one photosensitive substance is different from the at least one organic acidic substance, further wherein the at least one first and second nourishing elements may be the same or different, and even further The composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when combined with the composition) in whole or in part The ability to irrigate the plants to support the growth of the plants is compared to when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The composition may further comprise a third composition comprising at least one organic base material, optionally comprising at least one third nourishing element, the at least one third nourishing element being the same as the at least one first and second nourishing elements Or different, and the at least one organic base material is different from the at least one organic acid substance and the at least one photosensitizing substance.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising a first composition comprising at least one organic acidic material, the organic acidic material comprising at least one a trophic element; and a second composition comprising at least one photosensitive material, the photosensitive material comprising at least one second nourishing element, wherein the at least one photosensitive substance is different from the at least one organic acidic substance, further wherein The at least one first and second nourishing elements may be the same or different, and even further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in the pre-existing state, perhaps because of its corrected energy Spectroscopy) Effectively improves the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, as compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising a first composition comprising at least one organic acidic substance, the organic acidic substance comprising at least one first nourishing element; and one comprising at least one a second composition of the photosensitive material, the photosensitive material comprising at least one second nourishing element, wherein the at least one photosensitive substance is different from the at least one organic acidic substance, further wherein the at least one first and second nourishing elements The energy spectrum which may be the same or different, and even further wherein the composition possesses is more positive than the energy spectrum of the composition in the pre-existing state, the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when The ability of the composition to be fully or partially irrigated by saline to support plant growth when combined with the soil is compared to when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising at least one photosensitive material, the photosensitive material comprising at least one nourishing element, wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in a pre-existing state, the composition The material (perhaps because of its corrected energy spectrum) effectively improves the soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one photosensitive material comprising at least one nourishing element, wherein the energy spectrum possessed by the composition Corrected by the energy spectrum of the composition in the pre-existing state, the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when combined with the composition) to support plant growth, which is not It is good when the composition is combined.

The present disclosure also relates to an improved soil comprising a composition comprising at least one photosensitive material, the photosensitive material comprising at least one nourishing element, wherein the composition has an energy spectrum that is greater than the composition in a pre-existing state The energy spectrum is corrected and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising at least one photosensitive material, the photosensitive material comprising at least one nourishing element, wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in a pre-existing state, the composition The material (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil to support plant growth by irrigation with saline when combined with the composition, as compared to when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one photosensitive material comprising at least one nourishing element, wherein the energy spectrum possessed by the composition Corrected by the energy spectrum of the composition in the pre-existing state, the composition (perhaps because of its corrected energy spectrum) is effective in improving the soil (when combined with the composition), all or part of which is irrigated by saline to support plant growth. Ability, compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising at least one photosensitive material comprising at least one nourishing element, wherein the composition possesses an energy spectrum that is greater than the composition in a pre-existing state The energy spectrum is corrected, and the composition (perhaps because of its corrected energy spectrum) is effective in improving the ability of the soil to support plant growth by saline irrigation when combined with the composition, and when the soil is not combined with the composition Compare.

The present disclosure also relates to a composition comprising at least one organic acidic substance comprising at least one nourishing element, wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in a pre-existing state, the composition (perhaps Because of its corrected energy spectrum) it is effective to improve the ability of the soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one organic acidic substance comprising at least one nourishing element, wherein the energy spectrum possessed by the composition Corrected by the energy spectrum of the composition in the pre-existing state, the composition (perhaps because of its corrected energy spectrum) is effective in improving the ability of the soil (when combined with the composition) to support plant growth, which is less than the soil Good combination with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising at least one organic acidic substance comprising at least one nourishing element, wherein the composition possesses an energy spectrum that is greater than the composition in a pre-existing state The energy spectrum is corrected and the composition (perhaps because of its corrected energy spectrum) is effective in improving the ability of the soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising at least one organic acidic substance comprising at least one nourishing element, wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in a pre-existing state, the composition (perhaps Because of its corrected energy spectrum) the ability to effectively improve the soil (when combined with the composition) is fully or partially irrigated by saline to support plant growth, as compared to when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising at least one organic acidic substance comprising at least one nourishing element, wherein the energy spectrum possessed by the composition Corrected by the energy spectrum of the composition in the pre-existing state, the composition (perhaps because of its corrected energy spectrum) is effective in improving the soil (when combined with the composition), all or part of which is irrigated by saline to support plant growth. Ability, compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising at least one organic acidic substance comprising at least one nourishing element, wherein the composition possesses an energy spectrum that is greater than the composition in a pre-existing state The energy spectrum is corrected and the composition (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, and the soil does not The composition is compared when combined.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% Agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, relative to the total of the first composition Weight of the weight; the second composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1 % zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, based on the total weight of the second composition, and the second composition further comprises about 1.5 ppm of 5-ALA, Based on the total weight of the second composition; and the third composition comprises stalk powder, and At least one of the first, second, and third nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in a pre-existing state, perhaps because of its correction The energy spectrum) effectively improves the ability of the soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and About 1% ferrous sulfate, based on the total weight of the first composition; the second composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amine base Acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, by weight relative to the total weight of the second composition And the second composition further comprises about 1.5 ppm of 5-ALA relative to the second composition The weight of the total weight; and the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the composition has an energy spectrum ratio The energy spectrum of the composition in a pre-existing state is corrected, the composition (perhaps because of its corrected energy spectrum) is effective to improve the ability of the soil (when combined with the composition) to support plant growth, which is not the composition of the soil Good combination of things.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, in relative Based on the total weight of the first composition; the second composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch. , about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, based on the total weight of the second composition, and the second composition Containing about 1.5 ppm of 5-ALA, based on the total weight of the second composition; and the third The secondary composition comprises a stalk powder, and wherein the at least one first, second and third trophic elements may be the same or different, and further wherein the energy spectrum possessed by the composition is greater than the energy spectrum of the composition in the pre-existing state Correction, the composition (perhaps because of its corrected energy spectrum) is effective in improving the ability of the soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% Agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, relative to the total of the first composition Weight of the weight; the second composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1 % zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, based on the total weight of the second composition, and the second composition further comprises about 1.5 ppm of 5-ALA, Based on the total weight of the second composition; and the third composition comprises stalk powder, and At least one of the first, second, and third nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in a pre-existing state, perhaps because of its correction The energy spectrum) is effective to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, as compared to when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and About 1% ferrous sulfate, based on the total weight of the first composition; the second composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid , about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, based on the total weight of the second composition, And the second composition further comprises about 1.5 ppm of 5-ALA, relative to the total of the second composition. The weight of the weight; and the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the composition has an energy spectrum ratio The energy spectrum of the composition in the pre-existing state is corrected, and the composition (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, and The soil is compared when not in combination with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, in relative Based on the total weight of the first composition; the second composition comprises about 70% stalk powder, about 10% phosphate rock granules, about 12% agricultural grade amino acid, about 4.5% corn or potato starch. , about 1% manganese sulfate, about 1% zinc sulfate, about 0.5% copper sulfate, and about 1% ferrous sulfate, based on the total weight of the second composition, and the second composition Containing about 1.5 ppm of 5-ALA, based on the total weight of the second composition; and the third The secondary composition comprises a stalk powder, and wherein the at least one first, second and third trophic elements may be the same or different, and further wherein the energy spectrum possessed by the composition is greater than the energy spectrum of the composition in the pre-existing state Correction, the composition (perhaps because of its corrected energy spectrum) is effective in improving the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, and when the soil is not combined with the composition Compare.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% Agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% molybdic acid Ammonium and about 0.4% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amine Base acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second composition further comprises about 1.5 ppm of 5-ALA, a weight of the total weight of the second composition; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements are the same or different, and further wherein the composition The energy spectrum possessed by the object is more positive than the energy spectrum of the composition in the pre-existing state, and the composition (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil (when combined with the composition) to support plant growth, It is better than when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, About 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% ammonium molybdate, and about 0.4% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% Copper sulphate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, relative to the total weight of the second composition The weight, and the second composition further comprises about 1.5 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein At least one of the first, second, and third nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in a pre-existing state, perhaps because of its correction The energy spectrum) effectively improves the ability of the soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% Ferrous sulfate, about 0.1% ammonium molybdate and about 0.4% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 8% phosphorus Ore particles, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate , about 0.2% ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second composition Further comprising about 1.5 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one of the first, second and third The nourishing elements may be the same or different, and further wherein the composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when The ability of the composition to support plant growth when combined with the soil is better than when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% Agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% molybdic acid Ammonium and about 0.4% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amine Base acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second composition further comprises about 2 ppm of 5-ALA to The weight of the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the composition The energy spectrum possessed is more positive than the energy spectrum of the composition in the pre-existing state, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when combined with the composition) is fully or partially irrigated by brine The ability to support plant growth is compared to when the soil is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, About 1% copper sulfate, about 1.5% ferrous sulfate, about 0.1% ammonium molybdate, and about 0.4% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% Copper sulphate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, relative to the total weight of the second composition The weight, and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein At least one of the first, second, and third nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in a pre-existing state, perhaps because of its correction The energy spectrum) is effective to improve the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, as compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 15% agricultural grade amino acid, about 5% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 1.5% Ferrous sulfate, about 0.1% ammonium molybdate and about 0.4% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 8% phosphorus Ore particles, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 5% water absorbing agent, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate , about 0.2% ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second composition Further comprising about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one of the first, second and third The nourishing elements may be the same or different, and further wherein the composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when The ability of the composition to support plant growth by saline irrigation when combined with the soil is compared to when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 12% phosphate rock granules, about 15% Agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax , by weight of the total weight of the first composition; wherein the second composition comprises about 57% stalk powder, about 13% phosphate rock granules, about 16% agricultural grade amino acid, about 7% Corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, and about 0.2% ammonium molybdate and about 0.8% borax, relative to the second composition The weight of the total weight of the article, and the second composition further comprises about 2 ppm of 5-ALA relative to the second composition a weight of the weight; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the composition has an energy spectrum ratio The energy spectrum of the pre-existing composition is corrected, and the composition (perhaps because of its corrected energy spectrum) is effective in improving the ability of the soil (when combined with the composition) to support plant growth, which is less than the composition of the soil. Good combination of things. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 12% phosphate rock granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate, About 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 57% stalk powder, about 13% phosphate rock granules, about 16% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, and about 0.2. % ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second The composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and the at least one of the first and second The third nourishing elements may be the same or different, and further wherein the composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil ( The ability to support plant growth when combined with the composition is better than when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 12% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2 % ammonium molybdate and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 57% stalk powder, about 13% phosphate rock granules, about 16% Agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, and about 0.2% ammonium molybdate and about 0.8% borax , the second composition further comprises about 2 ppm of 5-ALA by weight relative to the total weight of the second composition Based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein The composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when combined with the composition) to support plant growth. Capacity, which is better than when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 12% phosphate rock granules, about 15% Agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax , by weight of the total weight of the first composition; wherein the second composition comprises about 57% stalk powder, about 13% phosphate rock granules, about 16% agricultural grade amino acid, about 7% Corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, and about 0.2% ammonium molybdate and about 0.8% borax, relative to the second composition The weight of the total weight of the article, and the second composition further comprises about 2 ppm of 5-ALA relative to the second composition a weight of the weight; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the composition has an energy spectrum ratio The energy spectrum of the composition in the pre-existing state is corrected, and the composition (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, and The soil is compared when not in combination with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to an improved soil treated with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element a second composition and a third composition comprising about 70% selectivity comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises about 60% Stalk powder, about 12% phosphate rock granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% sulfuric acid Iron, about 0.2% ammonium molybdate and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 57% stalk powder, about 13% phosphate ore granules , about 16% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, and about 0.2% ammonium molybdate and About 0.8% borax, based on the total weight of the second composition, and the second composition further comprises 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements are The same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in the pre-existing state, the composition (perhaps because of its corrected energy spectrum) is effective to improve the soil (when and The ability to irrigate all or part of the saline to support plant growth when combined with the soil is compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 12% phosphate ore granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2 % ammonium molybdate and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 57% stalk powder, about 13% phosphate rock granules, about 16% Agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, and about 0.2% ammonium molybdate and about 0.8% borax , the second composition further comprises about 2 ppm of 5-ALA by weight relative to the total weight of the second composition Based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein The composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when combined with the composition) in whole or in part The ability to irrigate the plants to support the growth of the plants is compared to when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% Agricultural grade amino acid, about 5% fatty acid, about 5% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate And about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 9% phosphate rock granules, about 15% agricultural grade amine base Acid, about 5% fatty acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, and about 2% ferrous sulfate, relative to the second composition The weight of the total weight, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total weight of the second composition. a weight thereof; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is The energy spectrum of the composition in the presence state is corrected, and the composition (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil (when combined with the composition) to support plant growth, which is less than the composition of the soil Good combination. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 8% phosphate rock granules, about 15% agricultural grade amino acid, about 5% fatty acid, about 5% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60 % stalk powder, about 9% phosphate ore granules, about 15% agricultural grade amino acid, about 5% fatty acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate And about 2% ferrous sulfate, based on the total weight of the second composition, and the second composition Further comprising about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one of the first, second, and The three nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in the pre-existing state, the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when The ability to support plant growth when combined with the composition is better than when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% agricultural grade amino acids, about 5% fatty acids, about 5% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% sulfuric acid Ferrous, about 0.2% ammonium molybdate and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 9% phosphate ore Granules, about 15% agricultural grade amino acids, about 5% fatty acids, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, and about 2% ferrous sulfate, The second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition, and For the weight of the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the composition The energy spectrum possessed by the object is more positive than the energy spectrum of the composition in the pre-existing state, and the composition (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil (when combined with the composition) to support plant growth, It is better than when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 8% phosphate ore granules, about 15% Agricultural grade amino acid, about 5% fatty acid, about 5% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate And about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 9% phosphate rock granules, about 15% agricultural grade amine base Acid, about 5% fatty acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, and about 2% ferrous sulfate, relative to the second composition The weight of the total weight, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total weight of the second composition. a weight thereof; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is The energy spectrum of the composition in the presence state is corrected, and the composition (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, and The soil is compared when it is not combined with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 8% phosphate rock granules, about 15% agricultural grade amino acid, about 5% fatty acid, about 5% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60 % stalk powder, about 9% phosphate ore granules, about 15% agricultural grade amino acid, about 5% fatty acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate And about 2% ferrous sulfate, based on the total weight of the second composition, and the second composition Further comprising about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one of the first, second and third The nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in the pre-existing state, the composition (perhaps because of its corrected energy spectrum) is effective to improve the soil (when The ability to irrigate all or part of the saline to support plant growth when combined with the composition is compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 8% phosphate rock granules, about 15% agricultural grade amino acid, about 5% fatty acid, about 5% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60 % stalk powder, about 9% phosphate ore granules, about 15% agricultural grade amino acid, about 5% fatty acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate And about 2% ferrous sulfate, based on the total weight of the second composition, and the second composition Further comprising about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one of the first, second, and The three nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in the pre-existing state, the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when The ability to support plant growth by saline irrigation when combined with the composition is compared to when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% Agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax , by weight of the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% Corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, relative to the second composition The weight of the total weight of the article, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total of the second composition. a weight of the weight; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the composition has an energy spectrum ratio The energy spectrum of the pre-existing composition is corrected, and the composition (perhaps because of its corrected energy spectrum) is effective in improving the ability of the soil (when combined with the composition) to support plant growth, which is less than the composition of the soil. Good combination of things. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate, About 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2 % ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second time The composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and the at least one of the first and second The third nourishing elements may be the same or different, and further wherein the composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil ( The ability to support plant growth when combined with the composition is better than when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2 % ammonium molybdate and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% Agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax , and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition. Based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein The composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when combined with the composition) to support plant growth. Capacity, which is better than when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% Agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax , by weight of the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% Corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, relative to the second composition The weight of the total weight of the article, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total of the second composition. a weight of the weight; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the composition has an energy spectrum ratio The energy spectrum of the composition in the pre-existing state is corrected, and the composition (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, and The soil is compared when not in combination with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate, About 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2 % ammonium molybdate and about 0.8% borax, based on the total weight of the second composition, and the second time The composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and the at least one of the first and second The third nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in a pre-existing state, the composition (perhaps because of its corrected energy spectrum) is effective to improve the soil The ability to irrigate all or part of the saline to support plant growth when combined with the composition is compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2 % ammonium molybdate and about 0.8% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 17% phosphate rock granules, about 8% Agricultural grade amino acid, about 7% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 3% ferrous sulfate, about 0.2% ammonium molybdate, and about 0.8% borax , and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition. Based on the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein The composition has an energy spectrum that is more positive than the energy spectrum of the pre-existing composition, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when combined with the composition) in whole or in part The ability to irrigate the plants to support the growth of the plants is compared to when the soil is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 17% Agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5% ammonium molybdate and about 0.5% borax , by weight of the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 13% phosphate rock granules, about 15% agricultural grade amino acid, about 6% Corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5% ammonium molybdate, and about 0.5% borax, relative to the second composition The weight of the total weight of the article, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total of the second composition. a weight of the amount; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the composition has an energy spectrum ratio The energy spectrum of the pre-existing composition is corrected, and the composition (perhaps because of its corrected energy spectrum) is effective in improving the ability of the soil (when combined with the composition) to support plant growth, which is less than the composition of the soil. Good combination of things. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product. And the soil can be modified sufficiently that the plants grown therein can be irrigated in whole or in part by the brine.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 17% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate, About 2% ferrous sulfate, about 0.5% ammonium molybdate, and about 0.5% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 13% phosphate rock granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5 % ammonium molybdate and about 0.5% borax, based on the total weight of the second composition, and the second group The composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and the at least one of the first and second The third nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in the pre-existing state, the composition (perhaps because of its corrected energy spectrum) is effective to improve the correction The energy spectrum is sufficient to enable the composition to improve the ability of the soil (when combined with the composition) to support plant growth, which is better than when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 17% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5 % ammonium molybdate and about 0.5% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 13% phosphate rock granules, about 15% Agricultural grade amino acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5% ammonium molybdate, and about 0.5% borax , and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition. Relative to the weight of the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein The energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in the pre-existing state, and the composition (perhaps because of its corrected energy spectrum) is effective in improving the ability of the soil to support plant growth when combined with the composition. It is better than the soil when it is not combined with the composition.

The present disclosure also relates to a composition comprising about 15% of a first composition comprising at least one first nourishing element, about 15% of a second composition comprising at least one second nourishing element, and about 70% selectively comprising a third composition of at least one third nourishing element, by weight relative to the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 17% Agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5% ammonium molybdate and about 0.5% borax , by weight of the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 13% phosphate rock granules, about 15% agricultural grade amino acid, about 6% Corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5% ammonium molybdate, and about 0.5% borax, relative to the second composition The weight of the total weight of the article, and the second composition further comprises about 2 ppm of 5-ALA, relative to the total of the second composition. a weight of the amount; wherein the third composition comprises a stalk powder, and wherein the at least one first, second, and third nourishing elements may be the same or different, and further wherein the composition has an energy spectrum ratio The energy spectrum of the composition in the pre-existing state is corrected, and the composition (perhaps because of its corrected energy spectrum) effectively improves the ability of the soil (when combined with the composition) to be fully or partially irrigated by saline to support plant growth, and The soil is compared when not in combination with the composition. The present disclosure also relates to an improved soil produced, for example, by treating soil with the composition; with respect to an improved soil comprising the composition or an altered form comprising the composition; Improved plants grown in the soil or treated with the composition; and improved seeds and/or improved plants produced, for example, from plants grown in the modified soil or treated with the composition product.

The present disclosure also relates to an improved soil produced by treating soil with an effective amount of a composition comprising about 15% of a first composition comprising at least one first nourishing element, and about 15% comprising at least a second composition of a second nourishing element and a third composition comprising about 70% selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition The composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 17% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulphate, about 1.5% zinc sulphate, about 1% copper sulphate, About 2% ferrous sulfate, about 0.5% ammonium molybdate, and about 0.5% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 13% phosphate rock granules, about 15% agricultural grade amino acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5 % ammonium molybdate and about 0.5% borax, based on the total weight of the second composition, and the second group The composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition; wherein the third composition comprises stalk powder, and the at least one of the first and second The third nourishing elements may be the same or different, and further wherein the energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in a pre-existing state, the composition (perhaps because of its corrected energy spectrum) is effective to improve the soil The ability to irrigate all or part of the saline to support plant growth when combined with the composition is compared to when the soil is not combined with the composition.

The present disclosure also relates to an improved soil comprising a composition comprising about 15% of a first composition comprising at least one first nourishing element and about 15% comprising at least one second nourishing element. The composition and about 70% of the third composition selectively comprising at least one third nourishing element, based on the total weight of the composition; wherein the first composition comprises about 60% stalk powder, about 10% phosphate rock granules, about 17% agricultural grade amino acid, about 6% corn or potato starch, about 1.5% manganese sulfate, about 1.5% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5 % ammonium molybdate and about 0.5% borax, based on the total weight of the first composition; wherein the second composition comprises about 60% stalk powder, about 13% phosphate rock granules, about 15% Agricultural grade amino acid, about 6% corn or potato starch, about 1% manganese sulfate, about 1% zinc sulfate, about 1% copper sulfate, about 2% ferrous sulfate, about 0.5% ammonium molybdate, and about 0.5% borax , and the second composition further comprises about 2 ppm of 5-ALA, based on the total weight of the second composition. Relative to the weight of the total weight of the second composition; wherein the third composition comprises stalk powder, and wherein the at least one first, second and third nourishing elements may be the same or different, and further wherein The energy spectrum possessed by the composition is more positive than the energy spectrum of the composition in the pre-existing state, and the composition (perhaps because of its corrected energy spectrum) effectively improves the soil (when combined with the composition) in whole or in part The ability of saline irrigation to support plant growth is compared to when the soil is not combined with the composition.

In another aspect, the present disclosure is directed to a method of using a composition as disclosed herein for use in improving the quality of soil, plant growth, seeds, and/or plant products. The compositions disclosed herein may be used alone or in combination with other treatments for soil and/or plants: such as traditional commercial fertilizers; crop rotation; and the use of non-commercial fertilizers such as garden trims (such as grass and shrub trims) ), leaves, hay, straw, chopped bark, whole bark, sawdust, shells, wood chips, waste paper (such as chopped newspapers and cardboard), animal manure, compost, kitchen waste, whole trees, branches Or twigs, and / or trunks. For example, two materials may be mixed (at least one of which has been treated as disclosed herein) and applied to soil and/or plants; or they may be used without prior mixing, and may be applied sequentially or simultaneously to Soil and / or plants.

The present disclosure provides a method for treating soil comprising contacting the soil with an effective amount of a composition as disclosed herein to obtain an improvement in the quality of the soil, plant growth, seeds, and/or plant product.

The present disclosure also provides a method for treating soil comprising contacting the soil with an effective amount of a composition as disclosed herein to improve the ability of the soil to be fully or partially irrigated by saline to support plant growth.

The present disclosure also provides a method for treating a plant comprising contacting the plant with an effective amount of a composition as disclosed herein for a time sufficient to improve the quality of the plant growth, seed and/or plant product.

The present disclosure also relates to a method for treating soil comprising contacting the soil with an effective amount of a composition, wherein the composition comprises at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than the a relative energy state value of at least one nourishing element in a pre-existing state, the composition (perhaps because of a larger relative energy state value) effective to improve the ability of the soil (when combined with the effective amount of the composition) to support plant growth It is better than the soil when it is not combined with the composition.

The present disclosure also relates to a method for treating soil comprising contacting the soil with an effective amount of a composition, wherein the composition comprises at least one nourishing element, wherein the at least one nourishing element has a relative energy state value greater than the a relative energy state value of at least one nourishing element in a pre-existing state, the composition (perhaps because of a larger relative energy state value) effective to improve the soil (when combined with the effective amount of the composition) in whole or in part by brine The ability to irrigate to support plant growth is compared to when the soil is not combined with the composition.

The present disclosure also relates to a method for treating soil comprising contacting the soil with an effective amount of a composition, wherein the composition comprises a first composition comprising at least one organic acidic material, the organic acidic material comprising at least a first nourishing element; a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance; and a inclusion a third composition of at least one organic base material, the selectivity comprising at least one third nourishing element, the at least one organic base material being different from the at least one organic acidic substance and the at least one photosensitive substance, wherein the at least one first The second and third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than the first and second states of the pre-existing state a relative energy state value of at least one of the third nourishing elements, perhaps because of the first a greater relative energy state value of at least one of the second and third nourishing elements, and (alone or in combination) effective to improve the soil (when combined with the effective amount of the composition) to support the ability of the plant to grow, which is greater than the soil Not good when combined with the composition.

The present disclosure also relates to a method for treating soil comprising contacting the soil with an effective amount of a composition, wherein the composition comprises a first composition comprising at least one organic acidic material, the organic acidic material comprising at least a first nourishing element; a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance; and a inclusion a third composition of at least one organic base material, the selectivity comprising at least one third nourishing element, the at least one organic base material being different from the at least one organic acidic substance and the at least one photosensitive substance, wherein the at least one first The second and third nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than the first and second states of the pre-existing state a relative energy state value of at least one of the third nourishing elements, perhaps because of the first a relatively large energy state value of at least one of the second and third nourishing elements, and (alone or in combination) effective to improve the soil (when combined with the effective amount of the composition) is wholly or partially irrigated by saline to support plant growth Ability, compared to when the soil is not combined with the composition.

The present disclosure also relates to a method for improving the growth of a plant comprising contacting the plant with an effective amount of a composition, wherein the composition comprises a first composition comprising at least one organic acidic material, The organic acid substance comprises at least one first nourishing element; and/or a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishing element, the at least one photosensitive substance and the at least one The organic acid is different, wherein the at least one first and second nourishing elements may be the same or different, and further wherein at least one of the first and second nourishing elements has a relative energy state value greater than the pre-existing state A relative energy state value of at least one of the first and second nourishing elements.

The present disclosure also relates to a method for treating soil comprising contacting the soil with an effective amount of a composition, wherein the composition comprises at least one nourishing element, and further wherein the composition of the composition has an energy spectrum ratio The energy spectrum of the composition of the state of existence is corrected, and the composition (perhaps because of the corrected energy spectrum) effectively improves the ability of the soil (when combined with the effective amount of the composition) to support plant growth, which is not This composition is good when combined.

The present disclosure also relates to a method for treating soil comprising contacting the soil with an effective amount of a composition, wherein the composition comprises at least one nourishing element, and further wherein the composition of the composition has an energy spectrum ratio The energy spectrum of the composition in the presence state is corrected, and the composition (perhaps because of the corrected energy spectrum) is effective to improve the ability of the soil (when combined with the effective amount of composition) to support the growth of the plant by saline irrigation, and The soil is compared when it is not combined with the composition.

The present disclosure also relates to a method for treating soil comprising contacting the soil with an effective amount of a composition, wherein the composition comprises a first composition comprising at least one organic acidic material, the organic acidic material comprising at least a first nourishing element; a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance; and a inclusion a third composition of at least one organic base material, the selectivity comprising at least one third nourishing element, the at least one organic base material being different from the at least one organic acidic substance and the at least one photosensitive substance, wherein the at least one first The second and third nourishing elements may be the same or different, and further wherein the energy spectrum (alone or in combination) possessed by at least one of the first composition, the second composition, and the third composition is sufficiently positive In order to improve the ability of the soil to support plant growth when combined with the effective amount of the composition, the ratio The soil is good when it is not combined with the composition.

The present disclosure also relates to a method for treating soil comprising contacting the soil with an effective amount of a composition, wherein the composition comprises a first composition comprising at least one organic acidic material, the organic acidic material comprising at least a first nourishing element; a second composition comprising at least one photosensitive substance, the photosensitive substance comprising at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance; and a inclusion a third composition of at least one organic base material, the selectivity comprising at least one third nourishing element, the at least one organic base material being different from the at least one organic acidic substance and the at least one photosensitive substance, wherein the at least one first The second and third nourishing elements may be the same or different, and further wherein the energy spectrum (individually or in combination) possessed by at least one of the first composition, the second composition, and the third composition is greater than The energy spectrum of the pre-existing state composition is sufficiently corrected to improve the soil (when with the effective amount of the group) When binding) can be wholly or partially by a saline irrigation to the ability to support plant growth, compared with the case when the soil is not combined with the composition.

The present disclosure also relates to a method for treating a plant to improve plant growth comprising contacting the plant with an effective amount of the composition according to the invention for a sufficient period of time. In some embodiments, the composition comprises a first composition comprising at least one organic acidic material, the organic acidic material comprising at least one first nourishing element; and/or a second comprising at least one photosensitive material a secondary composition, the photosensitive material comprising at least one second nourishing element, the at least one photosensitive substance being different from the at least one organic acidic substance, wherein the at least one first and second nourishing elements may be the same or different, and further wherein At least one of the first and second compositions possesses an energy spectrum that is more positive than an energy spectrum of at least one of the first and second compositions in a pre-existing state, perhaps due to a corrected energy spectrum Effectively improving the growth of the plant when combined with the effective amount of the composition.

The "required time" required to improve plant growth (when the plant is contacted (e.g., by spraying) with the composition described herein) is sufficient to achieve improved contact time for improved plant growth. . This time can be determined by routine experimentation.

In order to achieve a successful treatment, the soil and/or plant may be applied one or more times as disclosed herein, for example, about monthly, every three months, about every year, or for further embodiments, at each Before, during and/or after the growing season.

In order to determine an "effective amount of composition" in the context of an energy-treated composition as disclosed herein, soils that have been treated with a composition having an enhanced energy characteristic as defined herein and/or Plants grown in soil treated with this composition having an increased energy profile as defined herein are observed to see if they have attained at least one of the advantages disclosed herein. If at least one of those advantages is achieved, the composition is used in an effective amount.

In certain embodiments, the compositions disclosed herein can vary from about 300 kilograms per hectare (here, "kg/ha", ie, 20 kilograms per acre of soil (this "kg/mu") to about An amount of 15,000 kg/ha (ie, 1000 kg/mu) is applied to the soil. The area is measured in terms of "mu", and the "mu" used herein is equal to an area of about 666.7 square meters. For example, the composition can The following amounts are applied, such as 375 kg/ha (25 kg/mu), 750 kg/ha (50 kg/mu), 1500 kg/ha (100 kg/mu), 1800 kg/ha (120 kg/mu), 2250 Kg/ha (150 kg/mu), 3000 kg/ha (200 kg/mu), 3750 kg/ha (250 kg/mu), 5250 kg/ha (350 kg/mu), 5400 kg/ha (360 kg) /mu), 6000 kg/ha (400 kg/mu), 6750 kg/ha (450 kg/mu) or 12,000 kg/ha (800 kg/mu). Of course, the average person will know the minimum amount of the composition. Will be effective, for example, for soil and/or plant growth improvement, and/or for treating plants, and/or for achieving disclosure herein The amount of any other desired result.

In some embodiments, the composition can be applied to the soil in an amount varying from about 0.1 kilogram to about 20 kilograms per tree or plant per tree or plant. For example, the composition can be applied in the following amounts, such as 1 kg/tree or plant, 1.5 kg/tree or plant, 2 kg/tree or plant, 2.5 kg/tree or plant, 3 kg/tree or plant, 3.5 kg/tree Or plants, 4 kg/tree or plant, 4.5 kg/tree or plant, 10 kg/tree or plant or 15 kg/tree or plant. Again, one of ordinary skill will appreciate that the minimum amount of the composition will be effective, for example, for soil and/or plant growth improvement, and/or for treating plants.

The compositions as disclosed herein can be contacted with soil in a variety of ways. For example, the composition can be mixed with the soil, or the composition layer can be placed on or in the soil. As a further embodiment, the composition can be sprinkled or sprayed onto the topsoil. As another example, the composition can be in contact with soil adjacent to the plant. As a further embodiment, the soil (whether or not plants are grown therein) may be ploughed to form channels, such as channels having a width of about 10 cm to 50 cm and a depth of about 5 cm to 30 cm; or comparable channels and may be mutually The spaced apart pits, however the channels tend to be continuous. The composition can be placed in the channel in a variety of ways, such as by spreading and spraying. The channel can then be covered by tumbling or other things such as topsoil and soil coverings. For example, plowing is performed to maximize the uniformity of mixing of the soil with the compositions disclosed herein. Irrigation can also assist in trying to maximize the uniform mixture of soil and the composition. As a further example, the compositions disclosed herein can be applied to the soil as a base application prior to planting, such as at spring. As for the other composition, the compositions disclosed herein can be applied one or more times after planting and prior to collection. When the compositions disclosed herein are applied more than once after planting, those applications may be referred to as "fertilization."

Compositions as disclosed herein can also be contacted with plants. For example, the composition can be sprinkled or sprayed onto any part of the plant, such as the leaves, roots, leaves, stems, stems, branches, seeds, and/or flowers of the plant. As another embodiment, the composition can be contacted with the plant when the composition is in contact with soil of a neighboring plant.

The composition can be in contact with both soil and plants. For example, in addition to being in direct contact with a portion of the plant, the composition can be contacted with the plant by mixing the composition with the soil of any part of the growing plant or plant.

When a composition comprising the first, second and third compositions as disclosed herein is used, any two of the first, second and third compositions may be combined prior to contact with the soil and/or plant. Or three. The first, second and third compositions may also be in contact with the soil and/or plant, respectively (synchronously or sequentially). For example, the first and second compositions in liquid form can be sprayed (separately or pre-mixed) onto the plant while the third composition is contacted with the soil of the adjacent plant.

The present disclosure also relates to a method for making improved soil comprising contacting the soil with an effective amount of the compositions disclosed herein. The present disclosure also relates to a method for producing improved plants, such as improved plant products and/or modified seeds, comprising treating a plant and/or seed with an effective amount of the composition disclosed herein. Time to improve the plant and/or seed. The present disclosure also relates to a method for producing improved seeds comprising treating plants and/or seeds with an effective amount of the compositions disclosed herein for a sufficient period of time to modify the seed. The present disclosure also relates to a method for producing a plant capable of providing an improved plant product comprising treating the plant with an effective amount of the composition disclosed herein for a sufficient period of time such that the plant provides an improved plant product.

Without being bound by theory, the soil can be modified by the compositions and methods as disclosed herein below. For example, the materials in the first and second compositions, after being applied to the soil and/or plants as disclosed herein, can retain the altered energy state long enough to aid energy absorption. , energy storage and / or energy transfer. Further, for example, when the composition disclosed herein is mixed with a virgin soil such as sand, it may retain the altered energy state long enough to aid in the formation of microaggregates and/or flocculants, either of which may Helps to improve the soil, or this can form a changed energy state that can occur independently of each other. At least one organic acid present in the compositions disclosed herein may purify the surface of the virgin soil (such as sand) and may form a film around the soil particles so that microaggregates may be desirably formed; possibly with other ingredients (such as organic Colloid) assists in improving the soil. Organic colloids may also be present in the compositions disclosed herein in amounts sufficient to provide a flocculating agent. The formation of microaggregates may promote energy absorption, energy storage, and/or energy transfer from the altered energy state, as mentioned above. The formation of microaggregates may also be intended to promote soil permeability and promote the introduction of sunlight into the soil (substantially providing permeability to the treated soil due to structural changes caused by the composition disclosed herein in the soil) More daylight to provide increased energy into the roots, and this increased energy can be transferred into the leaves of the plants to increase photosynthetic synthesis in the plants), and to maintain nutrient and/or soil water levels (for the treated Soil can be supplied as a water reservoir). In one embodiment, brine (such as seawater) may be used, in whole or in part, as a source to provide the water and nutrients needed for the plant to grow in the soil that is mixed with the compositions disclosed herein.

Thus, in certain embodiments, the soil treated with the compositions disclosed herein (such as virgin soil) advantageously does not require as much water or as much non-saline water as would be expected to be used in which the plants are grown. Conversely, too much water can destroy the excellent microaggregate structure that the compositions disclosed herein can form in the treated soil. The views of the present disclosure can be excellent in areas where the water supply is insufficient in the world. In one embodiment, for example, the treated soil has a water content ranging from 25% to 35% by weight (relative to the total weight of the soil). The microaggregates that are desired to be formed can also provide an environment suitable for bacterial growth, which is generally excellent for the health of the plant roots. Of course, the energy-treated compositions disclosed herein may advantageously change when mixed with soil or applied to plants and/or seeds.

Furthermore, without being bound by theory, plant growth and/or grain yield can be improved as follows. The nourishing elements (such as N, P, and/or K) in the compositions disclosed herein may be more readily absorbed by the plant, perhaps because of the altered energy state achieved by the present disclosure. For example, if a plant is grown in a treated soil, energy from components in the treated composition, such as a photosensitive material having an appropriate energy spectrum and/or relative energy state value, can be transferred to the soil and/or Or plants that cause a series of beneficial photochemical reactions on or in plants to aid plant growth. As explained above, without being bound by theory, the compositions disclosed herein can be designed to have those energy spectra and/or relative energy state values that mimic (by themselves or when mixed with the target soil) good soil. Then, under further non-limiting theory, the treated soil and/or plant can achieve those desired energy spectra and/or relative energy state values, or at least in the target soil and/or plant energy spectrum and/or Or a sufficient improvement in relative energy state values to result in improved soil and/or plant growth as disclosed herein.

Of course, the average skilled person will understand that unsuitable or harmful environmental conditions (eg, lack of sunlight, natural disasters (such as floods), and cold temperatures) can adversely affect the effects of the compositions and methods disclosed herein, even in this article. The energy spectra and/or relative energy state values of the disclosed compositions are those sought.

As a further embodiment, the electromagnetically-treated photosensitive material can, for example, be provided as an electron pump (when combined with the target soil) to provide the energy required for the photochemical reaction of the following molecular structural changes:

Those photochemical reactions may be desirable to increase the interfacial hydrophilicity of the treated soil, making it more water absorbing and substantially transforming the soil into a more reminiscent state of the reservoir.

Furthermore, the compositions disclosed herein, at least one of which has an appropriate energy spectrum and/or relative energy state value, can be provided as an electronic pump in the treated plant, providing the mitochondria of the plant to be absorbed in the air. The O ₂ and the energy required to convert it to water are shown below:

4e ^- +4H ⁺ +O ₂ +nH ⁺ (internal mitochondria) → 2H ₂ O+nH ⁺ (external mitochondria)

Compositions as disclosed herein may also be desired to increase the biological response of plant roots if they are applied, for example, as a liquid to soil or plant leaves and/or bark and/or roots. This allows plants to absorb more energy from sunlight and increase plant cell growth, creating more adenyl triphosphate (ATP) (which provides chemical energy for plant growth). Furthermore, the biological response to plant activation due to this disclosure may be intended to increase cell size and enhance the thickness of the plant cell wall so that plant cells can contain more water in the cell wall for growth purposes. In this connection, a plant in a camel-like manner can advantageously have sufficient water to sustain growth for a longer period of time as the environment becomes dry.

The present disclosure also relates to a composition in a pre-existing state as disclosed herein. This pre-existing composition may also achieve at least one of the results as disclosed herein, although the results may not be as good as those achieved by the same composition that has been subjected to energy treatment as disclosed herein. In other words, all of the compositions having the ingredients disclosed above but not energized can have utility in accordance with the present disclosure.

The actual experiment conducted by the present disclosure based on (but not necessarily the same) is further illustrated by the following non-limiting examples.

Example Example 1

The starting materials for the six compositions according to the present disclosure are as described below, as in the energy treated form (BGA1-BGA6) in Examples 2-10. Table 1 shows the percentage of raw materials used to make BGA1-BGA6. The percentages of certain materials in Table 1 are each relative to the weight of the corresponding first or second composition.

BGA1 contains 15% of the first composition, 15% of the second composition, and 70% of the third composition, based on the weight of the total weight of BGA1. As seen in the table, the first composition contains 70% stalk powder, 10% phosphate ore granules, 12% agricultural grade amino acid, 4.5% eucalyptus powder, 1% manganese sulfate, 1% zinc sulfate, 0.5. % copper sulfate and 1% ferrous sulfate, based on the weight of the total weight of the first composition. The second composition comprises 70% stalk powder, 10% phosphate rock granules, 12% agricultural grade amino acid, 4.5% maize powder, 1% manganese sulfate, 1% zinc sulfate, 0.5% copper sulfate and 1% Ferrous sulfate, based on the total weight of the second composition, and further comprising 1.5 ppm of 5-ALA, based on the total weight of the second composition. This third composition contains stalk powder. The N content of BGA1 is about 2% by weight (relative to the total weight of BGA1). BGA1 can be used to treat a variety of types of soil to make it more suitable for plant growth.

In a typical embodiment, 5-ALA is first introduced into a sufficient amount of water, for example, from 1 liter to 3 liters of water per second of BGA1 composition. Then, the other components of the second composition of the BGA1 can be mixed while the 5-ALA/water mixture is sprayed onto the other components of the second composition of the BGA1 during mixing, and can be in the BGA1 A uniform 5-ALA distribution was obtained in the second composition. This method can be used in other specific examples of the second composition of BGAs described herein. When the weight percentage and/or ppm of each component of the second composition of the BGAs is calculated, the amount of water used to distribute 5-ALA is not considered to be part of the weight of the second composition of the BGAs. The second composition can then be mixed with the first and/or third composition, and a uniform 5-ALA distribution can be obtained in the resulting mixture.

BGA2 comprises 15% of the first composition, 15% of the second composition, and 70% of the third composition, based on the total weight of the BGA2. As seen in the table, the first composition is made by mixing 60% stalk powder, 10% phosphate ore granules, 15% agricultural grade amino acid, 5% eucalyptus powder, 5% APP, 1% manganese sulphate. 1% zinc sulfate, 1% copper sulfate, 1.5% ferrous sulfate, 0.1% ammonium molybdate and 0.4% borax (based on the total weight of the first composition). The second composition is obtained by mixing 60% stalk powder, 8% phosphate ore granules, 15% agricultural grade amino acid, 6% eucalyptus powder, 5% APP, 1% manganese sulfate, 1% zinc sulfate, 1% copper sulfate, 2% ferrous sulfate, 0.2% ammonium molybdate and 0.8% borax (based on the weight of the total weight of the second composition), and further comprising 2 ppm of 5-ALA ( It is based on the total weight of the second composition. This third composition contains only stalk powder.

BGA2 may be suitable for treating a variety of soil types to make it more suitable for plant growth, for example, dry soil, such as desert sand.

BGA3 contains 15% of the first composition, 15% of the second composition, and 70% of the third composition, based on the total weight of the BGA3. The first composition comprises 60% stalk powder, 12% phosphate rock granules, 15% agricultural grade amino acid, 6% maize powder, 1.5% manganese sulfate, 1.5% zinc sulfate, 1% copper sulfate, 2% Ferrous sulfate, 0.2% ammonium molybdate and 0.8% borax, based on the total weight of the first composition. The second composition comprises 57% stalk powder, 13% phosphate ore granules, 16% agricultural grade amino acid, 7% eucalyptus powder, 1.5% manganese sulphate, 1.5% zinc sulphate, 1% copper sulphate, 2% Ferrous sulfate and 0.2% ammonium molybdate and 0.8% borax, based on the total weight of the second composition, and further comprising 2 ppm of 5-ALA, relative to the second composition The weight of the total weight. This third composition contains stalk powder.

BGA3 may be suitable for treating a variety of soil types to make it more suitable for plant growth, for example, high altitude soil or nutrient deficient soil.

BGA4 contains 15% of the first composition, 15% of the second composition, and 70% of the third composition, based on the total weight of the BGA4. The first composition comprises 60% stalk powder, 8% phosphate ore granules, 15% agricultural grade amino acid, 5% stearic acid, 5% eucalyptus powder, 1.5% manganese sulphate, 1.5% zinc sulphate, 1 % copper sulfate, 2% ferrous sulfate, 0.2% ammonium molybdate and 0.8% borax, based on the total weight of the first composition. The second composition comprises 60% stalk powder, 9% phosphate ore granules, 15% agricultural grade amino acid, 5% stearic acid, 6% eucalyptus powder, 1% manganese sulfate, 1% zinc sulfate, 1 % copper sulfate and 2% ferrous sulfate, based on the total weight of the second composition, and further comprising 2 ppm of 5-ALA, relative to the total weight of the second composition meter. This third composition contains stalk powder.

BGA4 may be suitable for treating a variety of soil types to make it more suitable for plant growth, for example, saline and/or alkaline soils.

BGA5 contains 15% of the first composition, 15% of the second composition, and 70% of the third composition, based on the total weight of the BGA5. The first composition comprises 60% stalk powder, 17% phosphate rock granules, 8% agricultural grade amino acid, 7% maize powder, 1.5% manganese sulfate, 1.5% zinc sulfate, 1% copper sulfate, 3%. Ferrous sulfate, 0.2% ammonium molybdate and 0.8% borax, based on the total weight of the first composition. The second composition comprises 60% stalk powder, 17% phosphate rock granules, 8% agricultural grade amino acid, 7% maize powder, 1.5% manganese sulfate, 1.5% zinc sulfate, 1% copper sulfate, 3%. Ferrous sulfate, 0.2% ammonium molybdate and 0.8% borax, based on the total weight of the second composition, and further comprising 2 ppm of 5-ALA, relative to the second composition The weight of the total weight. This third composition contains stalk powder.

BGA5 can be adapted to treat a variety of soil types to make it more suitable for plant growth, for example, acidic soils.

BGA6 contains 15% of the first composition, 15% of the second composition, and 70% of the third composition, based on the total weight of the BGA6. The first composition comprises 60% stalk powder, 10% phosphate rock granules, 17% agricultural grade amino acid, 6% maize powder, 1.5% manganese sulfate, 1.5% zinc sulfate, 1% copper sulfate, 2% Ferrous sulfate, 0.5% ammonium molybdate and 0.5% borax, based on the weight of the total weight of the first composition. The second composition comprises 60% stalk powder, 13% phosphate rock granules, 15% agricultural grade amino acid, 6% maize powder, 1% manganese sulfate, 1% zinc sulfate, 1% copper sulfate, 2% Ferrous sulfate, 0.5% ammonium molybdate and 0.5% borax, based on the total weight of the second composition, and further comprising 2 ppm of 5-ALA, relative to the second composition The weight of the total weight. The third composition contains stalk powder.

BGA6 may be suitable for treating a variety of soil types to make it more suitable for plant growth, for example, soiled soils, for example, suffering from harmful viral or bacterial annoyances.

The agricultural grade amino acid comprises 47% to 51% of a mixture of 17 amino acids available from Penghe Biochemical Company, Nanhe County, Hebei Province, China. Copper sulfate and manganese sulfate are commercially available from Zouping Yongxing Chemical Company of China. Zinc sulfate was purchased from Beijing Yushenghong Chemical Co., Ltd. in China. Ferrous sulfate and borax are commercially available from Tianjin Tongxin Chemical Company of China.

For each of the above BGA1-BGA6, the raw materials of the first composition and the raw materials of the second composition are electromagnetically respectively in a plastic container wound around the coil or in a shielded chamber enclosed at room temperature. deal with. In the following embodiments 2-4, 6, 8, and 9, the AC current generator used to generate an AC current to flow in the processing apparatus to generate an electromagnetic field for electromagnetic processing is supplied at a voltage of 110 or 220 volts and 36. Operating at amperage current. This treatment was carried out for 1 hour as the frequency of the AC current was gradually changed from a temperature of 25 Hz to a fixed rate of 10,000 Hz. In Examples 5, 7 and 10, as the frequency of the AC current changes from 500 Hz at a fixed rate to 1500 Hz (at a working voltage of 10-15 volts and an operating current of 0.06-6 amps in the coil) The electromagnetic treatment was for 45 minutes. The supply voltage is at 110 or 220 volts. In Example 5, BGA2 and BGA4 as treated were mixed, and again, the mixture was treated under the same conditions as the respective BGA raw materials used in the electromagnetic treatments of Examples 7 and 10.

Example 2

The soil samples collected from Langfang, China were treated using the BGA1 referenced above. The soil samples from Langfang are sandy loam. In particular, the soil samples are individually mixed with 1:1 weight: BGA1, urea, diammonium phosphate, and Sylt's sulfur-based high-concentration compound fertilizer, which can be obtained from Anhui Province, China. Alte Fertilizers is commercially available, each containing 15% of each of N, P and K (based on the weight of the total weight of the fertilizer).

Immediately after mixing, the relative energy state values of N were obtained using the same N standard (i.e., using the same machine) for each evaluation as described above. The relative energy state values obtained for the following N: Langfang soil samples alone, BGA1 alone, urea alone, diammonium phosphate alone, Sylt brand sulfur-based high concentration compound fertilizer alone, 1:1 Langfang soil sample plus Mixture of BGA1, 1:1 Langfang soil sample plus urea mixture, 1:1 Langfang soil sample plus diammonium phosphate mixture, and 1:1 Langfang soil sample plus fertilizer mixture.

As shown in Figure 5A, for the Langfang soil sample alone (indicated as "soil" in Figure 5A), the relative energy state value of N is 5, and for BGA1 alone (indicated as "BGA1") 9. For urea alone (indicated as "urea"), 10, for diammonium phosphate alone, 8 for Sylt fertilizer alone (indicated as "fertilizer"), 6 for 1:1 Langfang The mixture of soil sample and BGA1 (indicated as "soil + BGA1") is 12, the mixture of 1:1 Langfang soil sample and urea is 11, and the mixture of 1:1 Langfang soil sample and diammonium phosphate is Said system 9, and for the mixture of 1:1 Langfang soil samples and fertilizers.

As shown in Figure 5A, BGA1 increases the relative energy state value of N in the Langfang soil sample, which is greater than that achieved with any untreated urea, diammonium phosphate, and fertilizer.

Without being bound by theory, the relative energy state values revealed by N according to this experiment may not be directly proportional to the nitrogen content in the composition. For example, the nitrogen content in BGA1 is only about 2% (relative to the total weight of BGA1), whereas the nitrogen content in urea is 46.7%. However, although the N system in urea is 23 times increased, the value of N in urea is not as high as the energy state value of BGA1. However, as mentioned above, the relative energy state value of N in the BGA1 treated Langfang soil sample is greater than the N value in the urea treated soil, although urea is not energy treated. Even though the relative energy state values of N increase in soil plus urea, soil plus diammonium phosphate, and soil plus fertilizer, those are comparative examples and are not disclosed in the soil because urea, diammonium phosphate, and fertilizer are not as good. Energy treated as disclosed herein. And as explained, the relative energy state value of N in the soil plus BGA1 (as disclosed herein by the energy treatment, the soil embodiment disclosed herein) is increased more than in the comparative example, perhaps because of the energy treatment .

Similarly, the relative energy state values of P were obtained as described herein: Langfang soil samples alone, BGA1 alone, diammonium phosphate alone, Sylt's sulfur-based high concentration compound fertilizer, 1:1 Langfang soil The sample was mixed with a mixture of BGA1, a 1:1 Langfang soil sample plus a mixture of diammonium phosphate, and a 1:1 Langfang soil sample plus a mixture of fertilizers.

As shown in Figure 5B, BGA1 increases the relative energy state value of P in the Langfang soil sample, which is more than either diammonium phosphate or fertilizer.

Again, without being bound by theory, it is revealed from this experiment that the relative energy state value of P may not be directly proportional to the phosphorus content in the composition. For example, the chemical content of P (in terms of P ₂ O ₅ ) in BGA 1, diammonium phosphate, and fertilizer is 3%, 42%, and 15%, respectively. However, as shown in Figure 5B, the relative energy state values of P in BGA1, diammonium phosphate, and fertilizer are 10, 9, and 6, respectively. In this case, BGA1 is more useful for increasing the relative energy state value of P in Langfang soil samples than diammonium phosphate and fertilizers, which each have 14 and 5 times the minimum P amount. Even if the relative energy state values of P in soil plus diammonium phosphate and soil plus fertilizer are increased, those are comparative examples and are not disclosed in the soil herein because diammonium phosphate and fertilizer are not as disclosed herein. Energy processing. And as explained, the relative energy state values of P in soil plus BGA1 (energy treated as disclosed herein, in the soil examples disclosed herein) increase more than in the comparative examples, perhaps Because of this energy treatment.

Similarly, the relative energy state values of K were obtained as described herein: Langfang soil samples alone, BGA1 alone, potassium sulfate alone, Sylt brand sulfur-based high concentration compound fertilizer alone, 1:1 Langfang soil samples plus BGA1 mixture, 1:1 Langfang soil sample plus potassium sulfate mixture, and 1:1 Langfang soil sample plus fertilizer mixture.

Again, without being bound by theory, the relative energy state values of K revealed by this experiment may not be directly proportional to the potassium content in the composition. The chemical content of K in BGA 1, potassium sulphate and fertilizer (in terms of K ₂ O) is 3%, 45% and 15%, respectively. However, the values of the relative energy states of K in BGA1, potassium sulfate, and fertilizer are 8, 8, and 6, respectively. In the 1:1 Langfang soil sample plus BGA1 mixture, 1:1 Langfang soil sample plus potassium sulfate mixture and 1:1 Langfang soil sample plus fertilizer mixture, the relative energy state values are 8 , 9 and 8. Thus, in terms of increasing the relative energy state value of K in the soil, BGA1 is only slightly worse in value than potassium sulfate (even when the amount of K is 15 times less), but it can be compared with fertilizer. Even if it is used 5 times less. And again, without being bound by theory, it does not matter how the electromagnetically treated BGA composition disclosed herein works to achieve the desired result. The present disclosure clarifies how those compositions are made and used to achieve at least one desired result. Even if the relative energy state values of K in the soil plus potassium sulphate and soil plus fertilizer are increased, those are comparative examples and are not disclosed in the soil herein because the potassium sulphate and fertilizer are not as energy as disclosed herein. deal with. And in this particular example, the relative energy state value of K in soil plus BGA1 (energy treated as disclosed herein, disclosed in the soil embodiment herein) is less than in the comparative example. By.

Example 3

BGA5 (which has 5% total N, P and K, relative to the total weight of BGA5) is also used to treat sugar cane fields in Hainan, China. The soil in the sugar cane garden is brick red and slightly acidic. About a month after planting sugar cane, a portion of the soil of the sugar cane plant (ie, an area of about 200 square meters) is ploughed to form a channel between the sugar cane plant that has a width and depth of about 15 cm to 20 cm. Approximately 750 kg/ha (50 kg/mu) of BGA5 was applied to the channel and then covered by tumbling. About two months after the first application, BGA5 was similarly applied to the same portion of the garden a second time in about the same amount. About two months after the second application, BGA5 was applied a third time to the same portion of the garden in about the same amount.

Another part of the sugar cane plant (i.e., also about 200 square meters) was provided as a control to measure the effect of BGA5. This part of the garden was not treated with BGA1. Instead, in a manner similar to the application of BGA5 (ie, a total of three times, about every two months), a high Norwegian concentration of compound fertilizer is applied in this part at an amount of about 30 kg/mu (available from China's Hainan agricultural resources). The company (Hainan Agricultural Resources Company, Ltd.) is commercially available, each containing 45% of total N, P and K, based on the total weight of the fertilizer, and an amount of KCl of about 10 kg/mu. 10 kg / mu of urea.

After almost 7 months of growth, the sugar cane yield (measured in terms of sugar cane weight per acre) grown in the various parts of the garden was measured. The sugar cane yield grown in the soil treated with BGA5 was numerically greater than about 38.6% by weight of sugar cane grown in the control soil. For evaluation, sugar cane was collected from a 10 meter column in both the BGA5 treated and control portions of the park. The weight of the stem was measured and then averaged to produce the 38.6% value described above.

Example 4

BGA2 was used in experimental fields in the Herlinger desert region of China. Chinese pine and Siberian almond trees (600 strains each) were planted in the experimental field. About half of the pine trees and half of the almond trees are treated with BGA2. In particular, the roots of the tree are treated with BGA2 (approximately 1-1.5 kg/tree) and the ridges are formed around the roots by winding an agricultural plastic film (volume about 15 cm x 20 cm x 30 cm), which is 1:50 (BGA2). The ratio of soil to water is a mixture of BGA2 and sand from the desert (the pine tree also has some non-sand soil around the roots; the almond tree does not). The plastic film is properly removed prior to planting and no water is applied to the tree when planted. The other half of the two species of trees were not treated with BGA2, providing a control for measuring the effects of BGA2. The trees are naturally irrigated by rain; but there are no additional irrigation schedules.

About six years after planting, the survival rate of pine and almond trees not treated with BGA2 is about zero. The survival ratio of the pine tree treated with BGA2 was about 73%, while the survival rate of the almond tree treated with BGA2 was about 19%.

One and a half years after planting the tree as described above, soil samples were collected from the roots of the trees treated with BGA2 and the trees provided as controls. Particle size analysis was performed on soil samples using a Mastersizer instrument from Malvern Instrument, and the results are shown graphically in Figures 12A and 12B. Figure 12A shows the particle size distribution of sand/loamy sand that has not been treated with BGA2. Figure 12B shows the particle size distribution of sandy loam obtained by treating sand/loamy sand with BGA2. Particles in soil samples were analyzed for clay, sand and mud sand. For example, a particle type clay type having a size of less than about 0.002 mm, a particle type mud sand type having a size of about 0.02 mm to 0.002 mm, and a particle type sand type having a size of about 2 to 0.02 mm. As shown in Table 2 below, soil samples collected from roots that were not treated with BGA2 (indicated in Table 2 as "soil samples not treated with BGA2") had 1.19% clay, 6.90% mud sand, and 91.91%. Sand (based on the weight of the total weight of the untreated soil sample), thus based on the International Soil Texture Triangle Charting System as shown in Figure 12C, which is sand/loice sand. Soil samples collected from the area around the roots treated with BGA2 (indicated in Table 2 as "BGA2 treated soil samples") had 3.68% clay, 38.34% mud sand and 57.96% sand (relative to treated) The weight of the total weight of the soil sample) is therefore sandy loam. See Figure 12C. Figure 12C shows that in the international soil texture triangulation for soil classification, sand/loamy sand that is not treated with BGA2 is at point A and shows sand/sedimented sand treated with BGA2 The sandy loam obtained from the soil is at point B. In addition, after treatment with BGA2, the desert sand soil around the roots treated with BGA2 is advantageously converted from sandy/loll sand to sandy loam. Both soil and plant growth (as judged from the above-mentioned survival ratio) were improved by treatment with BGA2.

Sandy loam is chemically different from sand/loamy sand, as measured about one month after sampling, as shown in Tables 3 and 4 below. In Table 3, all parameters reported were from soil samples taken approximately six years after planting. In Table 4, all parameters reported were from soil samples taken approximately one year after planting. For example, water retained in sandy loam (as shown in Table 3) is 11.1%, whereas in sand/loamy sand, the retained water is 0.9%. As a further example, the organic matter in sandy loam is 0.997%, whereas the organic matter in sand/loamy sand is 0.132%. As for even further examples, the total N in the sandy loam is 0.067%, whereas in the sand/loamy sand it is 0.007%. As a further example, the hydrolyzable N in the sandy loam is 105 mg/kg, whereas in the sand/loamy sand it is 5.51 mg/kg. Further, the total P in the sandy loam is 0.041%, whereas in the sand/loamy sand it is 0.019%. Even further, the cation exchange capacity in the sandy loam was 15.2 min/kg, whereas in the sand/loam sand it was 2.8 min/kg. As shown in Table 4, the bulk density of the soil samples treated with BGA2 was numerically lower than the soil samples not treated with BGA. The porosity of soil samples treated with BGA2 was numerically higher than that of soil samples not treated with BGA. The retained water content of the BGA-treated soil samples was numerically higher than the soil samples not treated with BGA. The water permeability rate of the soil samples treated with BGA was numerically higher than that of the soil samples not treated with BGA.

As also shown in Table 4, the BGA2-treated soil had a higher amount of agglomerates having a size of 1 mm or larger in the agglomerate content row. The BGA2-treated soil sample has a higher amount of agglomerates having a size of 0.25 mm or larger in the water-stabilized agglomerate content row.

All of the information reported in Tables 3 and 4 is based on the Research Institute of Agricultural Resources and Agricultural Regional Planning of China Agricultural Science Academy (formerly known as the Research Institute of Agricultural Resources and Agricultural Regional Planning of China Agricultural Science Academy). The measurements made for the "Research Institute of Soil Fertilizer" are based on data from the agglomerates and water-stabilized agglomerates in Table 4. Those data are based on measurements made at the University of Forestry in Beijing, China.

About six years after planting the tree as described above, a variety of nourishing elements were also obtained from soil samples collected around the root zone of the BGA-treated root and from soil samples around the root zone that provided the BGA2 effect as a control. Relative energy state value. As shown in Figure 6, in addition to Cu, Fe, and Mo, soil samples from the root zone of the BGA-treated tree were compared to soil samples of trees not treated with BGA2 (indicated as "untreated") The relative energy state values of N, P, K, Ca, Mg, S, Mn, Zn, and B, which are indicated as "treatment" in Fig. 6, are all numerically increased. Therefore, the relative energy state values of the nine nourishing elements in the soil treated by BGA are numerically increased, as measured about six years after the treatment. And those associated with soil improvement are associated, including improved particle size, chemical and physical characteristics, and plant growth improvement as mentioned above.

About six years after planting the tree as described above, an energy spectrum was also obtained for the following soil: a good soil sample from the forest of Altay, Xinjiang, China, which was used as standard soil in this example. For comparison purposes; soil samples from the root zone surrounding the BGA treatment; and soil samples from the root zone surrounding the effect of providing BGA2 as a control, as shown in Figure 7A, The energy spectrum of the treated soil sample mainly contains negative peaks (relative to the spectrum of the good soil), while the energy spectrum of the soil sample treated with BGA mainly contains positive peaks (as shown in Figure 7B), and under the positive curve The area is larger than the area under the positive curve of the good soil.

Example 5

In this example, a BGA mixture of 1:1 (by weight) ratio of BGA2 to BGA4 was prepared.

Again, electromagnetic treatment was carried out on the BGA mixture in a greenhouse at room temperature (see Example 1). The pretreated BGA is placed in a plastic bag, wound around the coil, and the AC current is gradually changed to a temperature of 1500 Hz at a fixed rate from 500 Hz in the coil, and the working voltage is 10-15 volts and the working is performed. The current was 0.06-6 amps for electromagnetic treatment for 45 minutes. The supply voltage is 220 volts.

The treated BGA mixture was applied to Abu Dhabi white sand in the Royal Garden of Abu Dhabi (described in more detail below). From the experimental field of the Royal Garden of Abu Dhabi, Abu Dhabi white sand samples were taken at a depth of 20 cm in most plant roots (as measured from the surface of Abu Dhabi white sand). The relative energy state values of the various nourishing elements in the following are measured as described herein: Abu Dhabi white sand (not indicated in Table 5 as "Abu Dhabi White Sand") and treated in the seawater that does not support plant growth. The BGA mixture (indicated as "BGA mixture") and the results are reported in Table 5.

A relative energy state value for the various nourishing elements is also measured for the mixture of Abu Dhabi white sand and the BGA mixture. Specifically, 10 grams of Abu Dhabi white sand was mixed with 2 grams of BGA mixture. The relative energy state values of the nourishing elements in the mixture of Abu Dhabi white sand and BGA were measured on the day when the mixture was first prepared (indicated as "mixture (Day 1)" in Table 5). The relative energy state value is measured periodically to monitor changes in the relative energy state values of the mixture. In this case, the relative energy state value is stabilized on the 7th day after mixing the Abu Dhabi white sand and BGA mixture. The relative energy state values measured on day 7 are shown in Table 5, "Mixture (Day 7)".

Then, the BGA mixture was applied to the test field for sowing wheat seeds in an amount of 120 kg/mu. About one month after treatment, 10 grams of soil samples were collected from the Abu Dhabi white sand test field (20 cm deep, as measured from the soil surface) treated with the BGA mixture, and the relative energy state values of various nourishing elements were tested (Table 5). Indicated as "treated soil (large scale) for one month").

As reported in Table 5, even on a large scale, the relative energy state values of all elements in the Abu Dhabi white sand treated with the BGA mixture were numerically improved, compared to the ABDA white sand without BGA treatment. Furthermore, no wheat growth was observed in Abu Dhabi white sand which was not treated with the BGA mixture. Wheat growth was observed in Abu Dhabi white sand treated with the BGA mixture.

Example 6

Use BGA3 to process experimental fields in China's Tibet. The test field is located at a high altitude in Lhasa Tibet and the field is barren. The total size of the test field is approximately 1840 square meters. About 240 square meters is dedicated to cucumbers and is divided into six test fields, each about 40 square meters. Among the three plots of the sub-test fields, BGA3 was applied to the soil at a rate of 250 kg/mu, and sheep manure was applied at a dose of 2500 kg/mu. In the other three sub-test fields, no BGA3 was applied and only a manure of 2500 kg/mu was applied. About 600 square meters is dedicated to cherry tomatoes, which are divided into fifteen test fields, each about 40 square meters. BGA3 was applied to the soil in an amount of 250 kg/mu in five of those sub-test fields. BGA3 was applied to the soil at an amount of 350 kg/mu in the other five of those sub-test fields. In the other five test fields, no BGA3 was applied. About 600 square meters is dedicated to bitter gourd, which is divided into fifteen test fields, each about 40 square meters. Among the five plots of the sub-test fields, BGA3 was applied to the soil at a rate of 250 kg/mu, and the sheep manure was applied to the soil at a dose of 2500 kg/mu. In the other five of those sub-test plots, BGA3 was applied to the soil at a dose of 350 kg/mu, and sheep manure was applied to the soil at a dose of 2500 kg/mu. In the other five test plots, no BGA3 was applied and only a manure of 2500 kg/mu was applied. About 400 square meters is dedicated to watermelon, which is divided into ten test fields, each about 40 square meters. Among the five plots of the sub-test plots, BGA3 was applied to the soil at a rate of 300 kg/mu, and the sheep manure was applied to the soil at a dose of 2500 kg/mu. In the other five test plots, no BGA3 was applied and only a manure of 2500 kg/mu was applied. In those experiments, soil that was not treated with BGA3 was provided as a control. The yield of each type of plant was measured for the total weight of the fruits of the individual plants. The yield increase was calculated from the average of the plants grown in the BGA3 treated soil in the described amount relative to the corresponding control plants grown in the soil not treated with BGA3 (measured sum divided by the number of measurements) (below the list) Indicated in 6 as an increase in the yield of the specific amount of BGA3 applied)). As shown in Table 6, for each plant product, BGA3 increased plant yield (compared to control plants) and thus numerically showed improved plant growth due to treatment of the soil with BGA3. And even in control experiments using sheep manure (a fertilizer) to treat the control soil.

Example 7

BGA4 was used to treat saline-alkaline soil samples collected from Tianjin, China. Samples of saline-alkaline soil from Tianjin were mixed at a ratio of 1:1 (by weight) with the following: BGA4, a high-concentration compound fertilizer based on sulfur, which is commercially available from Anhui Sierte Fertilizer Company The high-concentration compound fertilizer based on chlorine and based on the Sylt brand is commercially available from Anhui Sierte Fertilizer Company.

The saline-alkaline soil samples from Tianjin were also mixed with BGA4 and the fertilizer containing Cl, so the ratio of saline-alkaline soil samples: BGA4: fertilizer was about 1:1:1. Immediately after the mixture was prepared, the relative energy state values of Cl were obtained as described herein: saline soil sample, BGA4, fertilizer without Cl, fertilizer with Cl, 1:1 saline soil sample plus a mixture of BGA4, a 1:1 saline soil sample plus a mixture of fertilizers without Cl, a 1:1 saline soil sample plus a mixture of fertilizers containing Cl, and a 1:1:1 saline soil sample plus Cl Fertilizer plus a mixture of BGA4.

As shown in Figure 8, the relative energy state value of Cl in saline soil is the number 8. When the saline soil was treated with BGA4, the relative energy state value of Cl was numerically reduced to 5. Fertilizer without Cl has no numerical effect on the relative energy state values of Cl in saline soil. The fertilizer containing Cl increases the relative energy state value of Cl in the saline soil to a value of 9. However, when both BGA4 and the fertilizer containing Cl are present in the saline soil, the relative energy state value of Cl is numerically reduced to 6. Thus, BGA4 exhibits a value for the relative energy state value of the modified Cl when treating the soil, which clarifies that the harmful effects of excess Cl in the soil are reduced.

Example 8

BGA5 was used in the experimental field of the Three Gorges area in Chongqing, China. BGA5 was applied to one of the 120-mu experimental plots at a rate of 360 kg/mu. During the ten years after treatment with BGA5, farmers reported that crops grown in the test field treated with BGA5 (even without any other fertilizer applied) had better crops than those grown in the BGA5-treated portion of the test field. Yield.

Several decades after the application of BGA5, soil samples were collected from portions of the test field in the Three Gorges area that had been treated once with BGA5. Soil samples were also collected from portions of the test field in the Three Gorges area that had been treated only with conventional fertilizers.

Relative energy state value pairs of N, P and K were obtained for both soil samples treated with BGA5 and soil samples treated with conventional fertilizers (Table 7). Relative energy state values were measured by a J-1 quantum resonance spectrometer (commercially available from the Japan Society of Quantum Medical Research, as described herein) and are shown in Figures 9A, 9B and 9E.

The relative N, P, and K in the soil treated with BGA5 over 10 years ago, as shown in Table 7 and depicted in Figure 9F on a custom software supplied by a commercially available J-1 machine. The energy state values are still numerically higher than the relative energy state values of N, P and K in soils treated with only conventional fertilizers.

In a typical embodiment, 10 grams of soil sample is weighed into a sample container (such as a plastic bag) as shown, for example, in Figures 9C and 9D. The sample and container are then placed on the QRS as shown in Figure 9D. The user can operate the QRS according to the manufacturer's instructions, as shown in Figure 9E. The relative energy state values of the nourishing elements (eg, N, P, and K) selected by the user can be measured (see Figure 9E), and the measured values can now be displayed on the screen attached to the computer (see The values on the left-hand side of the screen in the 9F diagram (values "4", "5", and "4"); see Table 7 below), and cumulatively stored in memory for the convenience of the user, for example for comparison Relative energy state values of selected nourishing elements for different soil samples (see the value on the right hand side of the screen in Figure 9F (values "12", "13", "11", "4", "5" and "4"); see list 7 below). This method and machine can be used in other specific examples described herein.

Example 9

BGA6 was used to treat betel nut trees in Hainan, China, where the betel nut tree has been bothered by Pinang yellow disease found in the soil. BGA6 was applied to the betel nut soil in an amount of about 2 kg/tree.

Betel trees have dark brown roots before being treated with BGA6. About a month after the application of BGA6, the betel nut began to grow white new roots. Betel trees also have yellow leaves before being treated with BGA6. Two months after the application of BGA6, most of the leaves of the betel nut turn green.

The relative energy state values of various nourishing elements and harmful entities were also measured as follows: samples from normal soils of the same Hainan region but not sick, no sick soil samples treated with BGA6, and sick soil samples treated with BGA6.

The results are shown in Table 8.

As can be seen in the upper part of Table 8, the numerical relative energy state values of the various nourishing elements in the soil samples treated with BGA6 increased, compared to those soil samples that were not treated with BGA6 and even healthy soil. Further, as seen in the lower part of Table 8, the value of the relative physical state of the harmful entity in the soil treated with the composition was lower than or equal to the soil in which the disease occurred.

Example 10

A composition in water ("sBGA") as disclosed herein is prepared. First, a mixture is formed by dissolving a plurality of components in water, such that the mixture contains 250 kg/m3 of agricultural grade amino acid, 20 kg/m3 of copper sulfate, 50 kg/m3 of zinc sulfate, 30 kg. /m ^ metric manganese sulphate, 20 kg / m ^ 3 boric acid, 20 kg / m ^ m potassium sulfate and 2 g / m ^ 5 - ALA, adjusted to the weight of the total volume of the mixture and water 100% to form the sBGA.

When dissolving the ingredients, the mixture is agitated in a space enclosed by foil and at a speed of 50-100 r/min, while being placed in the space but away from the coil of the mixer. The mixture is electromagnetically treated. Electromagnetic treatment was carried out for 45 minutes at room temperature at a frequency of 500-1500 Hz, an operating voltage of 10-15 volts, an operating current of 0.06-6 amps and a supply voltage of 220 volts. The relative energy state values of N and K in the composition were individually measured, before the electromagnetic treatment, 23 and 24, and after the electromagnetic treatment, 47 and 48.

The sBGA was diluted with water at a ratio of 1:300 (by volume). The relative energy state values of the various nourishing elements in the sBGA and in the 1:300 diluted sBGA were obtained as disclosed herein, and are listed in Table 9, but no nourishment was measured in the pre-existing state, so no report was made. .

A comparative test of three different treatments of wheat seeds and/or soil in the Abu Dhabi white sand soaked in seawater:

Treatment 1: Wheat seeds were immersed in water until germination; when soaked, the water covered the wheat seeds; then, the soaked seeds were sown in an amount of 14 kg/mu in untreated seawater soaked in white sand.

Treatment 2: The wheat seeds were soaked in the diluted sBGA at a volume ratio of sBGA and water = 1:10 until germination; when soaked, the diluted sBGA covered the wheat seeds; then, the seeds soaked with sBGA were 14 kg/ The amount of acres is sown in the white sand of untreated seawater soaked.

Treatment 3: The wheat seeds were not soaked with water or any sBGA, but the white sand soaked in seawater was sprayed at a ratio of 75 kg/mu at a dilution of sBGA of 1:300 (volume ratio). Then, a BGA mixture of BGA2 and BGA4 in a weight ratio of 1:1 (as described in Example 5) was used to treat white sand soaked in seawater at a rate of 120 kg/mu, and then the amount was 14 kg/mu. The soaked seeds are sown in the treated white sand soaked in seawater.

The relative energy state values of various nourishing elements and harmful elements in the sample before and after treatment 3 are reported in Table 10. As can be seen from Table 10, the relative energies of various nourishing elements in the soil treated by the diluted sBGA at 1:300 (volume ratio) and the BGA mixture treated with BGA4 at a weight ratio of 1:1 (treatment 3) The state value is numerically increased, and the relative energy state values of the harmful elements (such as Na and Cl) are numerically reduced, compared to the untreated soil before treatment 3. In other words, white sand samples of seawater soaked were collected from the same portion of the test field before and after treatment 3.

The growth data of wheat plants and seeds are reported in Tables 11 and 12.

As shown in Table 11, according to Treatment 2 of the present disclosure, seeds immersed in sBGA took about 8 hours from planting to germination, and about 47 hours from planting to emergence. In contrast, without the treatment 1 of the present disclosure, the seeds of the soaking water are spent about 20 hours from planting to germination, and about 60 hours from planting to emergence. And in accordance with Treatment 3 of the present disclosure, the unsoaked seeds are spent about 49 hours from planting to emergence in the treated white sand soaked in seawater.

The "percentage of germination" as used herein is calculated as follows:

(number of germinated seeds / total number of seeds) × 100

Calculate the "extracted percentage" as used herein as follows:

(number of seeds emerging from soil / total number of seeds) × 100

As also shown in Table 11, the percentage of germination of the seed was 99.42% in the treatment 2 according to the present disclosure; and the percentage of germination of the seed in the treatment 1 not according to the present disclosure was 8.21%. Further, the percentage of seed exudation under treatment 2 according to the present disclosure was 98.25%, while the percentage of seed excavation under treatment 1 not according to the present disclosure was 7.22%. As can be seen, the percentage of seed exudation under Treatment 3 according to the present disclosure is similar to 98.11% of the seed line under Treatment 2 according to the present disclosure. In a particular embodiment disclosed herein, the germination % of the seed treated in the sand according to the present disclosure is at least 15%, 25%, 50%, 60%, 70%, 80%, 90% or 95%. In a particular embodiment disclosed herein, the seed treated in accordance with the present disclosure has at least 15%, 25%, 50%, 60%, 70%, 80%, 90%, or 95% exfoliated soil in the sand.

Further, as shown in Table 12, it reports the average growth rate and yield of the plant height of the seeds under Treatment 2 or 3 according to the present disclosure, but the plants of Treatment 1 are not reported in Table 12 because Very low germination and exudation percentages are reported in Table 11. Table 12 shows the time from seeding to collection of seeds under treatment 2 or 3 according to the present disclosure. In a particular embodiment disclosed herein, (1) plants grown in untreated sand and treated with the compositions disclosed herein and/or (2) sand treated with the compositions disclosed herein Plants grown in and/or (3) for the treatment of the compositions disclosed herein and for the growth of plants grown in the sand treated with the compositions disclosed herein and/or the biomass energy system is greater than not treated as such And/or the yield and/or biomass energy of the plants grown in the treated sand is at least 5%, 25%, 50%, 100%, 200%, 300%, 400%, 500%, 600. %, 700%, 800%, 900% or 1000%.

Example 11 Effect of Energy Processing on Relative Energy State Values

In this example, the raw material of BGA1 (explained in detail in Example 1) was used to evaluate the effect of different energy treatments of the feedstock. The raw material of the first composition (15% of the total weight of BGA1 is proposed in Example 1) and the raw material of the second composition (also proposed in Example 1 as 15% of the total weight of BGA1). This combination is referred to herein as "the first combination of two sub-compositions."

The first combination of the two sub-compositions is energy treated (indicated as "yes" in Table 12) or not energized (indicated as "NO" in Table 12) to form a first intermediate, and a third The secondary composition (proposed in Example 1 that 70% of the total weight of BGA1) was treated with or without energy to form a second intermediate. Then, two intermediates were combined, and either energy treated or not subjected to energy treatment to form Samples 1-7, as reported in Table 12, wherein Sample 1 is a comparative example and Samples 2-7 are specific examples of the present invention. For example, as reported in Table 12, when Sample 1 was produced, there was no intermediate or a combination of intermediates for energy treatment, so both the intermediate and combinations thereof were indicated as "No."

The materials were treated in an electromagnetic field generated by the processing apparatus as in Example 1, and each energy treatment was performed in this example and in Examples 12-14 described below. An AC current generator is used to generate an AC current to flow in the processing device to generate an electromagnetic field. The energy treatment was gradually changed from 1500 Hz at a fixed rate to 1500 Hz at a frequency of AC current in the coil, and at an operating voltage of 10.7 volts and an operating current of 0.06-6 amps for about 2 hours. The supply voltage is 220 volts.

The relative energy state values of N, P, and K for each of samples 1 through 7 were measured using a QRS J1 instrument as described herein and illustrated in Figure 9F. The relative energy state values obtained for N, P, and K of samples 1 through 7 are listed in the "N", "P", and "K" rows, respectively, and the relative energy state values obtained for N, P, and K. The sum is listed in the "N+P+K" row, which is reported in Table 13 below.

The sum of the relative energy state values of N, P, and K and the relative energy state values of N, P, and K measured for the first intermediate and the second intermediate are also reported in Table 13 below.

Example 12 Planting Shandong cabbage in a pot (Chinese cabbage)

Xiao Bai Cai (a type of Shandong cabbage ("Shandong Chinese cabbage") was used to evaluate the effects of Samples 1 to 7 as described in Example 11. 10.0 grams of samples 1 to 7 each with 1 kg of river The sands were combined to form potting soil. For each sample, potting soil was added to each of the five pots and watered.

Two days later, in each of the five pots, two Shandong cabbages were sown for each sample. After one week, trenches were dug in each pot and an additional 10.0 grams of each sample was added to and mixed in the corresponding trench. Five days later, the two strains of Shandong cabbage in each pot were removed and the other plants were left, leaving only one plant in each pot.

After about two weeks, each strain of Shandong cabbage was removed from each pot for all samples. For each removed Shandong cabbage, the soil was removed from the roots with water. After that, the water on each Shandong cabbage was removed, and each Shandong cabbage was weighed. For each of samples 1-7, the weight of each Shandong cabbage (indicated as plant 1 to plant 5) and the average weight of five Shandong cabbages (by adding the weights reported for each plant 1 to 5) And divided by 5) reported in Table 14.

For ease of comparison, the sum of the average weight of five cabbages planted in each of samples 1 to 7 and the relative energy state values of N, P and K of samples 1 to 7 are reported in Table 15. Using the average weight of five Shandong cabbages grown in sample 1 as a reference, the percentage increase in the average weight of Shandong cabbage grown in samples 2-7 is also reported in Table 15.

Example 13 Planting Experiment in the Field

Shandong cabbage was also grown in the field to evaluate the effects of the samples 1 to 7 proposed in Example 11. Prepare and mark each land with an area of approximately 1.0 square meter.

Then, 300 grams of Samples 1-7 each were combined with 0.1 cubic meters of river sand, and each combination was added to five plots for special samples and irrigation. Therefore, there are a total of 35 plots of land. Each sample was combined with river sand and provided in 5 plots of land for the sample. Two days later, 18 Shandong cabbages were planted in each of the 35 plots. One week later, an additional 200 grams of each of samples 1-7 was added to 5 labeled in a manner similar to that described for the pot experiment in Example 12 (ie, using grooves in each plot). Each piece of land in the sample. Five days later, 9 Shandong cabbages were removed from each of the 35 plots to leave 9 strains of Shandong cabbage in each plot. The basis for selection is to leave 9 plants that have been judged to have fairly consistent growth potential.

About two weeks later, each Shandong cabbage was removed from each plot. For each removed Shandong cabbage, the soil was removed from the roots with water, after which the water on each Shandong cabbage was removed, and then all nine Shandong cabbages removed from the special land were weighed together. The total weight of nine Shandong cabbages was obtained for each plot.

The total weight of nine Shandong cabbages from each plot and the average total weight of Shandong cabbage per plot are listed in Table 16. For example, in the column labeled Table 1 in Table 16, 18 strains of Shandong cabbage were planted in each of the five individual plots for the sample, each plot containing the combination of Sample 1 and the above-mentioned river sand. . After removing nine Shandong cabbages from each of the individual plots for Sample 1, the remaining nine Shandong cabbages were collected and the total weight of the nine Shandong cabbages was measured. This total weight is reported in the column labeled "Sample 1" in Table 16, labeled "Land 1". Similarly, the total weight of Shandong cabbages from the other four plots for land collection for sample 1 was measured and reported in the column labeled "Sample 1" in Table 16, labeled "Land 2", "Land" 3", "Land 4" and "Land 5" in the line. The average total weight of the Shandong cabbage per plot was calculated by adding together the weights reported for each of the plots 1 to 5 in the sample 1 column and dividing by 5 . The average total weight of Sample 1 is reported in the "Average Weight (kg) / Land" row of Table 16.

The sum of the average total weight of nine Shandong cabbages in the five plots of each of the samples 1 to 7 and the relative energy state values of N, P and K of the samples 1 to 7 are reported in Table 17. The average weights reported for each of Samples 2-7 in Table 17 are compared against the average weight of Sample 1 to calculate the percent increase in the average weight of Shandong cabbage using each of the samples 2-7. The percentage increase of samples 2-7 is reported in Table 17.

Example 14 Energy Treatment and Plant Experiment

In this example, (1) samples 1 and 4, as set forth in Example 11, and (2) urea, sold by Ningxia Yinchuan Fertilizer Co. as Liupanshan brand urea And (3) high-concentration compound fertilizer (Silter brand high-concentration compound fertilizer, 15-15-15, commercially available from China's Anhui Sierte Fertilizer Company, referred to herein as "fertilizer") is evaluated in relative Energy state values and effects on plant growth. The relative energy state values of N, P and K of samples 1 and 4 are described in Example 11. The relative energy state values of urea and fertilizer before and after the energy treatment were measured according to the procedure set forth in Example 11. This energy treatment was carried out as described in Example 11. The results are reported in the following list 18, where the wording "before" means "before energy processing" and the wording "after" means "after energy processing".

Shandong cabbage was planted in pots to test the effects of samples 1 and 4, and urea and fertilizer before and after energy treatment. The results and procedures for samples 1 and 4 are described in Example 12 and reported in Table 19.

In terms of fertilizers and urea, energy-treated fertilizers (2.0 g), energy-free fertilizers (2.0 g), energy-treated urea (4.5 g) and non-energy-treated urea (4.5 g) Combined with 1 kg of river sand to form potting soil. For each of the fertilizer and urea samples, the potting soil was added to each of the five pots and irrigated.

Two days later, two kinds of Shandong cabbage were planted for each of the five pots of fertilizer and urea samples. One week later, in a manner similar to that in Example 11, an additional 2.0 grams of fertilizer (energy treated or not) and 4.5 grams of urea (energy treated or not) were added to the five pots with fertilizer and urea. The sample corresponds to each pot. Five days later, two plants of Shandong cabbage were not grown and the other plants were removed from each pot, leaving only one plant in each pot.

After about two weeks, each Shandong cabbage was removed from each pot of fertilizer and urea samples. For each removed Shandong cabbage, the soil was removed from the roots with water. After that, the water on each Shandong cabbage was removed, and each Shandong cabbage was weighed. For each of the fertilizer and urea samples, the weight of each Shandong cabbage (indicated as plant 1 to plant 5) and the weight reported by each plant 1 to 5 were added together and divided by 5. The average weight of five Shandong cabbages is listed in Table 19.

The relative energy state values of samples 1 and 4, fertilizer (energy treated or not) and urea (energy treated or not) and the average weight of Shandong cabbage grown using it are also listed in Tables 20, 21 and 22, respectively. in.

Separate from Example 14, further comprising a method for treating soil comprising contacting the soil with an effective amount of the energy-treated composition, wherein the composition comprises at least one nourishing element, the composition is effective Improving the soil (when combined with the effective amount of the energy-treated composition) supports the ability of the plant to grow better than when the soil is not combined with the energy-treated composition.

Figure 1 shows an international soil texture triangle for the classification of certain soil types.

Figure 2 shows a flow chart of a method for making a composition according to one embodiment of the present disclosure.

Figure 3 shows a flow chart of a method for making a composition according to another embodiment of the present disclosure.

Figures 4A and 4B show a flow chart of a method for making a composition according to still another embodiment of the present disclosure.

Figure 5 shows the relative energy state values for N, P and K comparing the effects of the compositions according to the present disclosure with other conventional fertilizers. Figure 5A shows the relative energy state of the N values in the following materials: Langfang soil samples alone (soil), composition according to the present disclosure alone (BGA1), urea alone (urea), diammonium phosphate alone ((NH _{4 2} HPO ₄ ), Sylt's sulfur-based high-concentration compound fertilizer alone (commercially available from China's Anhui Silter Fertilizer Company) (fertilizer), 1:1 weight of Langfang soil samples Plus a mixture of BGA1 (soil + BGA1), a 1:1 weight of Langfang soil sample plus urea mixture (soil + urea), a 1:1 weight of Langfang soil sample plus a mixture of diammonium phosphate ( Soil + (NH ₄ ) ₂ HPO ₄ ) and a 1:1 weight of Langfang soil sample plus a mixture of high-concentration compound fertilizer (soil + fertilizer). Figure 5B shows the relative energy states of P values in the following materials: Langfang soil samples alone (soil), BGA1 alone (BGA1), diammonium phosphate alone ((NH ₄ ) ₂ HPO ₄ ), Sylt Sulfur-based high-concentration compound fertilizer (see above) alone (fertilizer), 1:1 weight of Langfang soil sample plus BGA1 mixture (soil + BGA1), 1:1 weight of Langfang soil sample plus A mixture of diammonium phosphate (soil + (NH ₄ ) ₂ HPO ₄ ) and a 1:1 weight of Langfang soil sample plus a mixture of high-concentration compound fertilizer (soil + fertilizer). Figure 5C shows the relative energy state of K values in the following materials: Langfang soil samples alone (soil), BGA1 alone (BGA1), potassium sulfate alone (K ₂ SO ₄ ), and Sylt's sulfur-based High-concentration compound fertilizer (see above) alone (fertilizer), 1:1 weight of Langfang soil sample plus BGA1 mixture (soil + BGA1), 1:1 weight of Langfang soil sample plus potassium sulfate Mixture (soil + K ₂ SO ₄ ) and a 1:1 weight of Langfang soil sample plus a mixture of high-concentration compound fertilizer (soil + fertilizer). In Figures 5A through 5C, this particular absolute value is based on a particular selected criterion. This standard will vary with the machine. Thus, depending on the machine used, the absolute number can vary, but the relative differences between different matrices (soil, BGAI, etc.) should be similar.

Figure 6 shows a desert sand sample (indicated as "untreated") not treated with the composition according to the present disclosure and a desert sand sample (indicated as "treatment") treated with the composition according to the present disclosure. Relative energy state values of N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, and Mo. In Figure 6, this standard will vary from machine to machine. Thus, depending on the machine used, the absolute number can vary, but the relative differences between different elements (such as N and P) should be similar.

Figure 7A shows the energy spectrum of a desert sand sample not treated with the composition according to the present disclosure. Figure 7B shows the energy spectrum of a desert sand sample treated with the composition according to the present disclosure. Figures 7A and 7B illustrate that the treated soil according to the present disclosure possesses an energy spectrum wherein the treated soil has a more "positive" area under the curve than the untreated soil. Of course, the particular absolute value of the area under the curve is based on a particular selection criteria. This standard will vary with the machine. Therefore, the absolute value of the area under the curve may vary depending on the machine used, but the relative difference between treated and untreated soil should be similar.

Figure 8 shows the relative energy state values of Cl in the following materials: salt Alkaline soil sample (saline soil), composition according to the present disclosure (BGA4), high concentration compound fertilizer without Cl (Silter brand sulfur-based high concentration compound fertilizer, available from China's Anhui Sylt Fertilizer company commercially available) (CF), high-concentration compound fertilizer containing Cl (Silter-based chlorine-based high-concentration compound fertilizer, commercially available from Anhui Silter Fertilizer Company, China) (CFCl) 1:1 by weight saline-alkaline soil sample plus BGA4 mixture (S+BGA4), 1:1 saline-alkaline soil sample plus a mixture of high-concentration compound fertilizer without Cl (S+CF), 1: 1 by weight of saline-alkaline soil sample plus a mixture of high-concentration compound fertilizer containing Cl (S+CFCl) and a 1:1:1 by weight saline-alkaline soil sample plus high-concentration compound fertilizer containing Cl and BGA4 Mixture (S+CFCl+BGA4). In Figure 8, this particular absolute value is based on a particular selected criterion. This standard will vary with the machine. Thus, depending on the machine used, the absolute number can vary, but the relative differences between the different matrices should be similar.

Figures 9A-9F show a complete commercially available device containing software that is used to measure as found in soil treated with BGA5 decades ago and as in Example 8 as it was decades ago. Describe the relative energy state values of the nourishing elements (such as N, P, and K) found in the soil that is fertilized.

Figures 10A and 10B show a complete commercially available device comprising a soft body for measuring the energy spectrum of a composition, soil and/or plant as disclosed herein.

Figure 11 graphically shows a coil wound around a container, wherein the coil is used to generate an electromagnetic field by flowing an AC current therethrough to process at least one material in the container.

Figure 12A shows the particle size distribution of sand/loamy sand that has not been treated with BGA2. Figure 12B shows the particle size distribution of sandy loam obtained by treating sand/loamy sand with BGA2. Figure 12C shows that in the international soil texture triangulation used for soil classification, the sand/loamy sand soil not treated with BGA2 is at point A, and is shown to be treated with BGA2 sand/sediment sand. The obtained sandy loam is at point B. Those patterns are related to the experiments reported in Example 4.

Claims (10)

A method for treating soil comprising: contacting the soil with an effective amount of the energy-treated composition, wherein the composition comprises at least one photosensitive material and at least one selected from the group consisting of N, P, K, Ca, Mg a nourishing element of S, Cu, Fe, Mn, Zn, B, Mo, and Se, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, When the soil is combined with the effective amount of the composition, the composition is effective to improve the ability of the soil to support the growth of the plant, which is better than when the soil is not combined with the composition. A method for treating soil comprising: contacting the soil with an effective amount of the energy-treated composition, wherein the composition comprises at least one photosensitive material and at least one selected from the group consisting of N, P, K, Ca, Mg a nourishing element of S, Cu, Fe, Mn, Zn, B, Mo, and Se, wherein the at least one nourishing element has a relative energy state value greater than a relative energy state value of the at least one nourishing element in a pre-existing state, When the soil is combined with the effective amount of the composition, the composition is effective to improve the soil to be supported by saline or in part to support plant growth when the soil is not combined with the composition. ability. A method for treating soil comprising: contacting the soil with an effective amount of the energy-treated composition, Wherein the composition comprises: a first sub-composition comprising at least one organic acidic substance, and a second sub-composition comprising at least one photosensitive substance, wherein the first At least one of the secondary composition and the second composition comprises at least one first nourishing element selected from the group consisting of N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo, and Se, wherein At least one photosensitive material is different from the at least one organic acidic substance, and a third sub-composition comprising at least one organic basic substance, the selectivity comprising at least one selected from the group consisting of N, P, K, a third nourishing element of Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo, and Se, the at least one organic basic substance being different from the at least one organic acidic substance and the at least one photosensitive substance, wherein the at least The first and third nourishing elements may be the same or different, and further wherein at least one of the first and third nourishing elements has a relative energy state value greater than at least the first and third nourishing elements in the pre-existing state One The relative energy state value of the species, when the soil is combined with the effective amount of the composition, the composition is effective to improve the ability of the soil to support plant growth, which is better than when the soil is not combined with the composition. A method for treating soil comprising: contacting the soil with an effective amount of the energy-treated composition, Wherein the composition comprises: a first composition comprising at least one organic acidic substance, a second composition comprising at least one photosensitive substance, wherein the first composition and the second composition are at least one of The first trophic element comprising at least one selected from the group consisting of N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo, and Se, wherein the at least one photosensitive material is associated with the at least one organic acid Different in substance, and a third composition comprising at least one organic base material, the selectivity comprising at least one selected from the group consisting of N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo and a third nourishing element of Se, the at least one organic basic substance being different from the at least one organic acidic substance and the at least one photosensitive substance, wherein the at least one first and third nourishing elements may be the same or different, and further wherein the first The relative energy state value possessed by at least one of the first and third nourishing elements is greater than the relative energy state value of the at least one of the first and third nourishing elements in the pre-existing state, when the soil and the effective amount of the composition When combined, compared to the soil when not bound to the composition, the composition can effectively improve the soil intended to wholly or partially by saline irrigation capabilities to support plant growth. A method for treating soil comprising: contacting the soil with an effective amount of the energy-treated composition, wherein the composition comprises: a first composition comprising at least one organic acidic substance, The organic acidic substance comprises at least one first nourishing element selected from the group consisting of N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo and Se, and a second time comprising at least one photosensitive substance a composition, the photosensitive material comprising at least one second nourishing element selected from the group consisting of N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo, and Se, the at least one photosensitive material Different from the at least one organic acidic substance, and a third composition comprising at least one organic basic substance, the organic basic substance selectively comprising at least one selected from the group consisting of N, P, K, Ca, Mg, S, Cu, Fe a third nourishing element of Mn, Zn, B, Mo, and Se, the at least one organic basic substance being different from the at least one organic acidic substance and the at least one photosensitive substance, wherein the at least one of the first, second, and third The nourishing elements may be the same or different, and further wherein at least one of the first, second and third nourishing elements has a relative energy state value greater than at least the first, second and third nourishing elements in the pre-existing state a relative energy state value when the soil When the effective amount of the binding composition, the composition effectively improve the ability of the soil to support plant growth, when not combined with lines of the composition ratio of the good soil. A method for treating soil comprising: contacting the soil with an effective amount of the energy-treated composition, wherein the composition comprises: a first composition comprising at least one organic acidic substance, the organic acidic substance Containing at least one first nourishing element selected from the group consisting of N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo, and Se, a second composition comprising at least one photosensitive material, the photosensitive material comprising at least one selected from the group consisting of N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo, and Se a trophic element, the at least one photosensitive material being different from the at least one organic acidic substance, and a third composition comprising at least one organic basic substance, the organic basic substance selectively comprising at least one selected from the group consisting of N, P, a third nourishing element of K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo, and Se, the at least one organic basic substance being different from the at least one organic acidic substance and the at least one photosensitive substance, wherein The at least one first, second, and third nourishing elements may be the same or different, and further wherein at least one of the first, second, and third nourishing elements possesses a relative energy state value greater than the pre-existing state a relative energy state value of at least one of the second and third nourishing elements, when the soil is combined with the effective amount of the composition, the composition may be compared to the soil when not combined with the composition Effective improvement The saline irrigation of the soil to support plant growth of the capability. The method of claim 1, wherein the soil before treatment is selected from the group consisting of sand/loamy sand, heavy clay, clay, sandy clay, sandy clay loam, silty clay, silty sand. Viscous loam and silt loam. A method for improving plant growth comprising: contacting the plant with an effective amount of the energy-treated composition for a sufficient period of time, wherein the composition comprises: a first composition comprising at least one organic acid The organic acidic substance comprises at least one selected from the group consisting of N, P, K, Ca, Mg, S, a first nourishing element of Cu, Fe, Mn, Zn, B, Mo, and Se, and/or a second composition comprising at least one photosensitive material, the photosensitive material comprising at least one selected from the group consisting of N, P, and K a second nourishing element of Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo, and Se, the at least one photosensitive material being different from the at least one organic acidic substance, wherein the at least one first and the first The two nourishing elements may be the same or different, and further wherein the relative energy state value possessed by at least one of the first and second nourishing elements is greater than the relative energy state of the at least one of the first and second nourishing elements in the pre-existing state value. A method for treating desert sand that does not support horticultural and/or agricultural plant growth to convert the sand into soil capable of supporting horticultural and/or agricultural plant growth, comprising: allowing the desert sand to be treated with an effective amount of energy Contact of the composition, wherein the composition comprises at least one nourishing element selected from the group consisting of N, P, K, Ca, Mg, S, Cu, Fe, Mn, Zn, B, Mo, and Se, further wherein the at least one nourishing element The relative energy state value possessed is greater than the relative energy state value of the at least one nourishing element in the pre-existing state, and when the desert sand is combined with the effective amount of the composition, the composition can effectively convert the desert sand into energy Soil that supports horticultural and/or agricultural plant growth. A method for treating soil comprising contacting the soil with an effective amount of an energy-treated composition, wherein the composition comprises at least one photosensitive material and at least one selected from the group consisting of N, P, K, Ca, Mg, S, Cu, The nourishing elements of Fe, Mn, Zn, B, Mo and Se, when the soil is combined with an effective amount of the energy-treated composition, the composition effectively improves the ability of the soil to support the growth of the plant, compared to the soil Good combination with energy-treated compositions.