EP3089953A2 - Mixed metallic crystalline orthophosphates for the temporally controlled release of trace elements in the rhizodermal and epidermal areas of plants - Google Patents

Abstract

In order to obtain an improved food stuff composition with respect to prior art, which releases the thus contained nutrients in a time-controlled manner in the rhizodermal and epidermal areas of the plants, the invention proposes a foodstuff composition for plants which contains at least one mixed metallic crystalline orthophosphate of the type [T_a(M1 M2 M3...Mx)_b(PO₄)_c n H₂o]. wherein T is selected from NH₄, K or CH₄N₂O - M1, M2, M3... Mx are metals which are selected from Mg, Ca, Mn, Fe, Co, Ni, Cu and Zn, - a = 0 or 1, wherein b = 3, when a = 0, and b = 1 when a = 1, and c = 2 when a = 0, and c = 1 when a = 1, and - 0 ≤ n ≤ 9. The mixed metallic crystalline orthophosphate contains at least two different metals M1, M2, M3... Mx, under the proviso that at least one of said at least two different metals is selected from Mn, Mg and Ca, wherein the total content of Mn, Mg and/or Ca is in the region of 0,5 - 90 mol-% with respect to the total amount of all metals contained in the mixed metal crystalline orthophosphate.

Description

 Mixed-metallic crystalline orthophosphates for the time-controlled release of trace elements in rhizodermal and epidermal areas of plants

The present invention relates to an effect-enhanced nutrient composition for the timed release of trace elements in rhizodermal and epidermal regions of plants. Moreover, the present invention relates to the use of such a nutrient composition in a method for fertilizing plants, with which a time-controlled release of trace elements in the rhizodermal and epidermal region of plants takes place. 1. Background of the invention

In order to ensure healthy growth, plants have to extract various nutrients from the soil in which they grow. However, many soils are deficient in certain elements, or they are present in a form unavailable to plants.

Enhanced Efficiency Fertilizers have certain formulations, contain specific additives, or have particular physical properties that have the potential to increase plant nutrient uptake, ideally to deliver a linear to sigmoidal nutrient delivery, with the goal of increasing nutrient delivery Need to synchronize in the course of plant growth and to protect the nutrients from reactions in the soil, or in the leaf application on the plant surface, which can reduce the availability of plants.

The supply of fertilizers can be done via the soil or by application to the above-ground parts of plants. In this way, nutrients, such as trace elements, can be provided in the rhizodermal or epidermal region of plants. The term rhizodermal refers here to the terminus tissue of the plant root, the rhizodermis. The term epidermal, in contrast, refers to the terminus tissue of the above-ground parts of plants, the epidermis. 2. State of the art

The majority of the effect-enhanced fertilizers inherently have high water solubility. The release of the nutrients it contains is essentially controlled by the water solubility of the formulation surrounding it. In some product types, the fertilizer particles are in a particular carrier matrix, such as e.g. a mixture of melted waxes, surfactants and polyethylene glycols embedded. However, to achieve the desired depot effect, this approach requires a large amount (up to 40%) of carrier material. In the case of fertilizers coated with polymer coatings, the release of the nutrients is highly dependent on the quality of the coating. If there are cracks in the coating, granules may directly release up to a third or more of the nutrients when in contact with water, and on the other hand, in part, one third of the nutrients are released only long after they are needed by the plant. These patterns of release vary significantly from the desired linear to sigmoidal form of nutrient delivery. Another disadvantageous aspect of polymer-coated fertilizers is that their use can result in undesirable accumulation of plastic debris in the treated floors.

Alternative effect-enhanced fertilizers are metal ammonium phosphates or metal potassium phosphates and partially acidified phosphate rock (PAPR), which by themselves can be termed inorganic, sparingly soluble compounds. A number of metal ammonium phosphates have been evaluated as fertilizers to be used for soil, for example U.S. Patent 3,125,411 or U.S. Patent 3,174,844. Probably the best known product of this type is magnesium ammonium phosphate as hexahydrate (including part of the "Guano").

US Pat. No. 3,574,591 describes slow-dissolving ammonium-potassium-metal polyphosphates having a straight or branched chain structure. In US 2010/0024026, virtually insoluble trace element fertilizers in the form of polymerized metal phosphates are described in water, which can go into solution in an acidified environment.

3. Object of the invention

The object of the present invention was to provide a prior art improved nutrient composition which timely releases the nutrients therein when the nutrient composition is provided in the rhizodermal and epidermal region of the plants. 4. Solution of the object of the invention

According to the invention a nutritional composition for plants, therefore it is proposed that at least one mixed metal crystalline orthophosphate type [T _a (M1 M2 M3 ... Mx) b (P04) c ^■ n H ₂ 0] contains wherein T is selected from NH _4, K or CH ₄ N ₂ O; and M1, M2, M3 ... Mx are metals selected from Mg, Ca, Mn, Fe, Co, Ni, Cu and Zn, the mixed metallic orthophosphate containing at least two different metals with the proviso that at least one of said at least two different metals M1, M2, M3 ... Mx is selected from Mn, Mg and Ca, the total amount of Mn, Mg and / or Ca being in the sum in the range from 0.5 to 90 mol% based on the total amount of all metals contained in the mixed metallic orthophosphate. In cases where a = 0, b = 3 and c = 2. In cases where a = 1, b = 1 and c = 1. Furthermore, the rule 0 £ n <9. 5. Advantages of the invention

There are enough trace elements in many soils, but these are often not available in bioavailable form. The reason for this is usually the low solubility of individual ions, such as that of iron, which is mainly present as an extremely poorly soluble Fe (III) oxide and hydroxide. The equilibrium concentration of iron present at a neutral pH free in the soil matrix is about 10 ^-17 M and thus far below the necessary requirement of 10 ^-6 to 10 ^-5 M of the crops To overcome these barriers to the problem of solubility Plants developed different strategies, especially for improved cation uptake.

One strategy of plants is to reduce rhizodermal pH by the mechanism of the 'proton pump' or by the targeted delivery of organic acids (e.g., malic and citric acids) through the plant root. As a result, the pH in the rhizosphere root zone can decrease by up to 2 pH gradients, and the acidification significantly increases the solubility and hence availability of metal ions, thus improving nutrient uptake.

A second possibility of nutrient uptake, especially of trace elements, is the absorption of ionic elements via the epidermal leaf surface into the plant parenchyma. At the leaf surface, nutrient crystals can slowly go into solution at low pH and thus be converted into an absorbable form. The pH change in the acidic region is exemplified by CO2, which when dissolved in water (film) on the Leaf surface carbonic acid forms (H2CO3), and also by acidic substances on the leaf surface (from the deposition of substances from the atmosphere), such as ammonium sulfate, ammonium hydrogen sulfate or "acid rain." According to the invention, therefore, a nutrient composition for plants is proposed that for Plant provides essential trace elements in an exchangeable or extractable form, wherein the nutrient composition has defined solubility properties The nutrient compositions according to the invention are characterized in particular by a low water solubility combined with high solubility in the acidic pH range Nutrient availability is not controlled by hydrolysis or diffusion rates, but can be actively induced by the treated plants.

By root exudates, such as organic acids (e.g., citric acid), or by actively lowering the pH in the rhizosphere root area in other ways (see above), the plants treated with the present nutritional compositions can specifically mobilize nutrients from the nutrient composition. Not only does this improve availability over time, it also reduces the uncontrolled release of nutrients to the environment, with optimal adjustment of the ratio of water and acid solubilities. It thus provides effective fertilizers with depot function, which ensure a timely controlled nutrient release in the rhizosphere of the treated plants, without causing excessive nutrient input into the environment. All this is achieved by providing mixed metallic orthophosphates in crystalline form in the nutrient compositions proposed by the invention, wherein at least two different metals are present in the crystal structure of the orthophosphates, with the proviso that at least one of these at least two different metals is Mn, Mg and Ca. with the further proviso that the total amount of Mn, Mg and / or Ca in the sum is in the range of 0.5 to 90 mol% based on the total amount of all metals contained in the mixed metallic orthophosphate.

The crystalline mixed metal orthophosphates of the present invention are salts of phosphoric acid which, unlike polyphosphates, are in uncondensed form. The crystalline mixed-metal orthophosphates of the present invention are characterized by a regular and continuous arrangement of the orthophosphate molecules and possibly existing crystal water in a crystal structure which can be detected by the reflections occurring in an X-ray diffraction analysis (see FIG. 8). The experiments of the inventors described in detail below have shown that the presence of Mn, Mg and / or Ca in the crystal structure allows the water and acid solubility of the mixed metallic orthophosphates to be adjusted individually.

A further advantage resulting from the crystal structure of the mixed-metal crystalline orthophosphates according to the invention is that the metals enclosed in the crystal lattice are protected from oxidative influences. Because plants prefer to receive bivalent metallic ions for nutritional reasons, the integrated trace elements in the mixed metallic crystalline orthophosphates of the present invention are preferably in the preferred bivalent absorption form of the plant (Fe ²⁺ , Mn ²⁺ , Cu ²⁺ , Zn ^{2 +} or Mg ²⁺ ). Especially in these cases, therefore, the protection against oxidative influences by including the metals in a crystal lattice of particular advantage. 6. Special embodiments of the invention

The advantages of the present invention are achieved by the claimed mixed-metal crystalline orthophosphates in which the total amount of Mn, Mg and / or Ca in the sum in the range of 0.5 to 90 mol% relative to the total amount of all in the ge mixed metallic orthophosphate metals contained.

The total amount of Mn, Mg and / or Ca in one embodiment of the invention is at least 5 mol%. In further embodiments of the invention, the total content of Mn, Mg and / or Ca is at least 10 mol%, at least 15 mol%, at least 20 mol% or at least 25 mol%. The upper limit of the total content of Mn, Mg and / or Ca in these embodiments is optionally up to 90 mol%, 85 mol%, up to 80 mol%, up to 75 mol% or up to 70 mol% ,

In certain embodiments, within the stated total content of Mn, Mg and / or Ca, the molar ratio of Mg or Ca or the sum of Mg and Ca on the one hand to Mn on the other hand is in the range of 0.5: 1 to 10: 1. In further embodiments of the invention, within the stated total content of Mn, Mg and / or Ca, the molar ratio of Mg or Ca or the sum of Mg and Ca on the one side to Mn on the other side is at least 1: 1, at least 2: 1 or at least 5: 1 and up to 10: 1 each.

An embodiment of the nutrient composition according to the invention is characterized in that within a period of up to 50 hours at most 10% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution, when continuously circulating 0.03 g of the mixed metallic crystalline orthophosphate in 30 ml of water at 25 ° C on a tumble mixer.

In a specific embodiment, the total amount of Mn, Mg and / or Ca is selected so that within a period of up to 50 hours at most 5% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution, if 0 , 03 g of mixed metallic crystalline orthophosphate continuously circulated in 30 ml of water at 25 ° C on a tumble mixer. In another specific embodiment, the total content of Mn, Mg and / or Ca is selected such that within a period of up to 50 hours at most 2.5% by weight of each of the metals contained in the mixed metallic orthophosphate in solution go when continuously circulating 0.03 g of the mixed metallic crystalline orthophosphate in 30 ml of water at 25 ° C on a tumble mixer.

One embodiment of the nutrient composition of the invention is characterized in that within a period of up to 100 hours, at most 20% by weight of each of the metals contained in the mixed metallic orthophosphate dissolves when 0.03 g of the mixed metallic orthophosphate in 30 ml of water at 25 ° C on a tumble mixer continuously circulated. In a specific embodiment, the total amount of Mn, Mg and / or Ca is selected so that within a period of up to 100 hours at most 10% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0 , 03 g of mixed metallic crystalline orthophosphate continuously circulated in 30 ml of water at 25 ° C on a tumble mixer. In a further specific embodiment, the total amount of Mn, Mg and / or Ca is selected so that within a period of up to 100 hours at most 5% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0.03 g of the mixed metallic orthophosphate in 30 ml of water at 25 ° C continuously circulated on a tumble mixer.

An embodiment of the nutrient composition of the invention is characterized in that within a period of up to 50 hours at least 25% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0.03 g of the mixed metallic orthophosphate in 30 ml of 1 mmol citric acid solution at 25 ° C on a tumble mixer continuously circulated.

In a specific embodiment, the total amount of Mn, Mg and / or Ca is selected such that within a period of up to 50 hours, at least 35% by weight of each of the in The metals contained in the mixed-metallic crystalline orthophosphate go into solution when continuously circulating 0.03 g of the mixed-metallic crystalline orthophosphate in 30 ml of 1 mmol citric acid solution at 25 ° C. on a tumble mixer. In a further specific embodiment, the total content of Mn, Mg and / or Ca is selected so that within a period of up to 50 hours at least 45% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0.03 g of mixed metallic crystalline orthophosphate continuously circulated in 30 ml of 1 mmol citric acid solution at 25 ° C on a tumble mixer. One embodiment of the nutrient composition of the invention is characterized in that within a period of up to 100 hours at least 35% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0.03 g of the mixed metallic orthophosphate in 30 ml 1 mmol citric acid solution at 25 ° C on a tumble mixer continuously circulated.

In a specific embodiment, the total amount of Mn, Mg and / or Ca is selected so that within a period of up to 100 hours, at least 45% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution, if 0 , 03 g of mixed metallic crystalline orthophosphate in 30 ml 1 mmol citric acid solution at 25 ° C continuously circulated on a tumble mixer. In a further specific embodiment, the total amount of Mn, Mg and / or Ca is selected so that within a period of up to 100 hours at least 55% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0.03 g of mixed metallic crystalline orthophosphate continuously circulated in 30 ml of 1 mmol citric acid solution at 25 ° C on a tumble mixer.

An embodiment of the nutrient composition of the invention is characterized in that within a period of up to 50 hours at least 75% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0.03 g of the mixed metallic orthophosphate in 30 ml 5 mmol citric acid solution at 25 ° C on a tumble mixer continuously circulated.

In a specific embodiment, the total amount of Mn, Mg and / or Ca is selected so that within a period of up to 50 hours at least 85% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution, if 0 , 03 g of mixed metallic crystalline orthophosphate in 30 ml of 5 mmol citric acid solution at 25 ° C continuously circulated on a tumble mixer. In a further specific embodiment, the total content of Mn, Mg and / or Ca is chosen to be within one At least 95% by weight of each of the metals contained in the mixed metallic orthophosphate in solution for up to 50 hours, when 0.03 g of the mixed metallic orthophosphate crystalline in 30 ml of 1 mmol citric acid solution at 25 ° C on a tumble mixer continuously circulates.

An embodiment of the nutrient composition according to the invention is characterized in that the total amount of Mn, Mg and / or Ca in the sum in the range of 2.5 to 80 mol%, preferably in the range of 5 to 75 mol% based on the Total amount of all contained in the mixed metallic orthophosphate metals.

An embodiment of the nutritional composition according to the invention is characterized in that the at least one mixed metal crystalline orthophosphate of the type [(M1 M2 M3 ... Mx) ₃ (P0 ₄₎ 2 ^■ n H ₂ 0], where M1, M2, M3 .. Mx are selected from Mg, Ca, Mn, Fe, Co, Ni, Cu and Zn, and where 0 -n <9.

An embodiment of the nutritional composition according to the invention is characterized in that the at least one mixed metal crystalline orthophosphate type [T (M1 M2 M3 ... Mx) (P0 ₄₎ ^■ n H ₂ 0], where T is selected from NH _4, K or (NH ₂ ) ₂ CO, wherein M1, M2, M ₃ ... M x are selected from Mg, Ca, Mn, Fe, Co, Ni, Cu and Zn, and where n <1.

An embodiment of the nutrient composition according to the invention is characterized in that the nutrient composition contains, in addition to the at least one mixed-metal crystalline orthophosphate, further additives selected from macro nutrients, micronutrients, complex fertilizers, organic fertilizers, plant strengthening agents, chelating and complexing substances or soil structure improvers. peat culture substrates, peat-free soils and unit earths.

In the embodiments of the invention in which the nutrient composition according to the invention contains further additives in addition to the at least one mixed-metal crystalline orthophosphate, the total amount of mixed-metal crystalline orthophosphate according to the invention contained in the nutrient composition is 5 to 90% by weight. In specific embodiments, the total amount of mixed metal crystalline orthophosphate according to the invention contained is at least 10% by weight, at least 15% by weight, at least 20% by weight or at least 25% by weight. In these embodiments, the total amount of mixed metal orthophosphate according to the invention contained is up to 70% by weight, up to 75% by weight, up to 80% by weight or up to 85% by weight. An embodiment of the nutrient composition according to the invention is characterized in that the nutrient composition is in the form of a suspension, a pulverized fertilizer, a granulated fertilizer, in the form of an enhanced efficiency fertilizer or in the form of a storage fertilizer with a defined slow release of nutrient (depot fertilizer) ,

The present invention also relates to the use of a nutrient composition of the aforementioned type for the time-controlled release of Mg, Ca, Mn, Fe, Co, Ni, Cu and / or Zn in the rhizodermal and epidermal region of plants. As the inventors have shown in detail below, by selecting suitable proportions of Mn, Mg and / or Ca in the crystal structure, the water and acid solubility of the mixed metallic orthophosphates can be individually adjusted.

The present invention therefore also encompasses a method for fertilizing plants, the method comprising providing a nutrient composition according to any one of the preceding claims in the rhizodermal and epidermal regions of the plants, wherein by selecting suitable proportions of Mn, Mg and / or Ca in the crystal structure, the water and acid solubility of the mixed metallic crystalline orthophosphates can be individually adjusted.

An embodiment of the method according to the invention is characterized in that in the method, the solubility of the at least one mixed metallic crystalline orthophosphate contained in the nutrient composition in water, in 1 mmol citric acid solution and / or in 5 mmol citric acid solution so chooses that in the at least one Gemischme - Metallic metals Mg, Ca, Mn, Fe, Co, Ni, Cu and / or Zn contained in the crystalline crystalline orthophosphate are released in a timely manner in the amount required for the particular plant and the given conditions.

7. Description of the application areas

The nutrient compositions according to the invention can be used as nutrient substances in all areas of plant nutrition, for example in agriculture, horticulture or forestry for nutrient supply in numerous plant crops. A preferred use of the metal P compounds of the present invention is in combination with other nutrient composition-supplementing macronutrients such as nitrogen, potassium and phosphate with secondary nutrient substances such as calcium, sulfate, magnesium and supplemental micronutrients. The nutrient compositions according to the invention can be used in multi-nutrient fertilizers, organic fertilizers or soil conditioners known to the person skilled in the art of agrochemistry or, for example, in the form of coatings or nutrient fillings of granulated fertilizer forms, for example in so-called controlled-release formulations (CRF) and, Release Formulations (SRF), in general, Enhanced Efficiency Fertilizers or Stock Fertilizers, including the classic Cultan application system (Controlled Uptake Long Term Ammonium Nutrition) containing nitrogen exclusively as ammonium or in a modified form by way of example based on urea / ammonium sulfate as a granulate or HAS solution, or urea / ammonium / nitrate as granules or AH solution) with a defined slow release of nutrient or in so-called condensed fertilizer forms.

The nutrient compositions according to the invention can be used as a nutrient substance in soil administration, in foliar application as well as for seed treatment. The nutritional compositions may be applied to the seed undiluted or, preferably, diluted. The application can be done before sowing.

The products according to the invention can be used in particular in the field of irrigation of crop plants (fertigation), which include, for example, systems of drip irrigation, microirrigation or hydroponics. The product according to the invention can be integrated into systems which surround and support the plant roots. These can be containers, pots, dishes, vessels or pressed systems (substrate and source tablets or blocks) made of different materials, such as clay, peat (eg Sphagnum white peat), coconut fiber, organic substrate, cellulose, Plastic, as well as carrier systems of exemplary gels, granulated expanded clay, gravel, basalt, perlite, coconut fiber or mineral wool (rock wool).

The metal P compounds according to the invention can be used as such or in their formulations also in admixture with fungicides, bactericides, acaricides, nematicides or insecticides known to the person skilled in the art, as well as herbicides and so-called safeners (substance which is added to a pesticide so that it not phytotoxic). In many cases, synergistic effects are obtained, ie the effectiveness of the mixture is greater than the effectiveness of the individual components. The active substances are obvious to the expert in crop protection and agrochemistry as mixing or application partners and can be found in the literature ("Pesticide Manual", 13th Ed. 2003, The British Crop Protection Council, London; U IImann's Agrochemicals, Vol 2, Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim, 2007). The nutrient compositions according to the invention can be administered with other nutrients and active substances simultaneously, sequentially or in combination. Each nutrient may be administered separately as a single component or in admixture with more than one component of a mixture or application.

The nutrient compositions according to the invention can be applied directly, ie without containing further components and without being diluted. In certain embodiments, the nutritional compositions are applied with other nutritional and active ingredients in the form of a suitable formulation or the use form prepared therefrom by further dilution. Examples of formulations are: water-soluble concentrates (SL, LS), dispersible concentrates (DC), emulsifiable concentrates (EC), emulsions (EW, EO, ES), suspensions (SC, OD, FS), water-dispersible and water-soluble granules (WG, SG), water-dispersible and water-soluble powders (WP, SP, SS, WS), gel formulations (GF), dusts (DP, DS), granules (GR, FG, GG, MG), ULV solutions (UL). In particular for seed treatment, water-soluble concentrates (LS), suspensions (FS), dusts (DS), water-dispersible or water-soluble powders (WS, SS), emulsions (ES), emulsifiable concentrates (EC) and gel formulations (GF), and for further applications active substance-impregnated natural and synthetic substances, encapsulations in polymeric substances and in encapsulants and used as "controlled-release" or "slow-release formulations". This list does not represent a limitation. The actual application form depends on the respective purpose; It should in any case ensure a fine and uniform distribution of the compound according to the invention.

The formulations used can be prepared in a manner known to those skilled in the art, e.g. by mixing the nutrient substances optionally with the addition of customary auxiliaries, such as, for example, fillers, carriers, diluents and / or solvents, furthermore using various surface-active agents, ie wetting agents, adhesives, dispersants or emulsifiers and / or foam-forming agents. The formulations mentioned can, according to the known manner of their preparation, further beneficial processing and formulation auxiliaries such as organic or inorganic thickeners, stabilizers, gelling agents, evaporation accelerators, defoamers, adhesives, antifreeze, siccatives, UV stabilizers and optionally dyes and pigments, as well as bactericides and antifreeze, etc. The formulation auxiliaries are added to the compound in the ratio of 30: 1 to 1:30, if desired.

The nutrient compositions according to the invention can be applied by treating the plants, seeds, plants, materials or the soil to be fertilized with an active substance. seed amount of the nutrient compositions by pouring, dipping, spraying, spraying, atomizing, vaporizing, injecting, silting, brushing, dusting, sprinkling, dry pickling, wet pickling, wet pickling, slurry pickling or encrusting, or in propagating material, in particular in seeds and vegetative plant parts continue treated by one or more layers, before or after sowing, or the setting of the plants or before or after emergence of the plants. The nutrient compositions may be applied simultaneously together or separately or sequentially.

The contents of the nutrient compositions of the use forms prepared from the commercial formulations can vary widely. The "effective amount" generally includes an agrochemical, quantitative composition of the nutrient compositions that economically increases the yield based on nutritional fertilizing effect.The "effective amount" can vary widely and is influenced by numerous factors, such as the weather and the climate , the growth stage of the culture or the pathogenic pest pressure. Accordingly, the "effective amount" can not be defined by definition, but the following information should nevertheless be given:

When using the nutrient compositions according to the invention, the application rates can be varied within a substantial range, depending on the mode of administration. In the treatment of agricultural crops, the application rates of nutrient composition may generally be between 10 to 50,000 g / ha, preferably between 100 to 25,000 g / ha, in particular 250 to 10,000 g / ha. In the case of seed treatment, the application rates of nutrient compositions may generally be between 0.001 and 100 g per kilogram of seed, preferably between 0.01 and 50 g per kilogram of seed, in particular between 0.1 to 25 g per kilogram of seed.

To the nutrient compositions, oils of various types, adhesives, wetting agents, surfactants, adjuvants (additive additives), herbicides, fungicides, other pesticides, bactericides, if appropriate, also only immediately before use (tank mix), can be added.

According to the invention, all plants and plant parts can be treated with the nutrient compositions. In this context, plants are understood as meaning all plants and plant populations, such as desired and undesired wild plants or crop plants (including naturally occurring crop plants). Crop plants can be plants which can be obtained by conventional breeding and optimization methods or by biotechnological and genetic engineering methods or combinations of these methods, including transgenic (genetically engineered) plants and including plant variety rights protectable or non-protectable plant varieties. Plant parts are to be understood as meaning all aboveground and subterranean parts and organs of the plants, such as shoot, leaf, flower and root, examples of which include leaves, needles, stems, stems, flowers, fruiting bodies, fruits and seeds, and roots, tubers and rhizomes. The plant parts also include crops and vegetative and generative propagation material, such as cuttings, tubers, rhizomes, offshoots and seeds. As examples of transgenic plants, the important crops, such as cereals (wheat, rice), maize, soya, potato, cotton, rapeseed, will be particularly emphasized. Of particular importance are the nutrient compositions for the fertilization of a variety of crops such as cereals (wheat, barley, rye, triticale, oats, rice, sorghum), beets (sugar and feed beets), pome, stone and berry fruit (apple, pear, Plums, peaches, almonds, cherries, brain, bromine, Preisel, Johannis, sting or strawberries), legumes (peas, beans, lentils, soybeans), oil crops (mustard, oilseed rape, poppy, olives, sunflowers, flax , Coconut, oil palm, castor, cocoa, peanuts), cucumbers (cucumbers, melons, squash), fiber plants (cotton, flax, hemp, jute), citrus fruits (oranges, lemons, tangerines, grapefruit), vegetable crops (cabbage and Salads, asparagus, spinach, carrots, onions, potatoes, tomatoes, peppers), laurel family (avocados, cinnamon or camphor), other plants such as bananas, corn, vines, sugarcane, nuts, coffee, tea, tobacco, hops, as well as energy and commodity plants such as corn, soybean, wheat, oilseed rape, Z sugar beet, sugar cane, oil palm or poplar and willow trees and also ornamentals and forest plants (perennials and perennials, conifers, composites, shrubs, trees) and grass as lawns as well as on the propagation material, for example seeds and the crop of these plants. This list does not represent a limitation. 8. Exemplary embodiments and figures

The mixed-metal crystalline orthophosphates used according to the invention differ in particular in their individual water and acid solubility. By selective combination of the main elements, including the elements Mn, Mg and / or Ca, and by adding certain doping metals, a certain ratio of the metals is set to each other, which leads to the individual water and acid solubility properties, as shown in the accompanying figures are.

Showing:

Figure 1 shows the results of Löslichkeitsversuchen with (FeMg) 3 (P0 ₄₎ 2 ^* 3 H2O,

FIG. 2 shows the results of solubility experiments with (FeMgMnCuZn) 3 (P0 ₄ ) 2,

FIG. 3 shows the results of solubility experiments with (FeMn) 3 (P0 ₄ ) 2, FIG. 4 shows the results of solubility experiments with (FeMnMgCuZnMoB) 3 (PO 4) 2, FIG. 5 shows the results of solubility experiments with N H 4 (FeMg) 3 (PO 4) 2,

Figure 6 shows the results of solubility experiments with N H4 (FeMnMg) 3 (P04) 2 and

Figure 7 shows the results of solubility experiments with N H4 (FeMnMg) 3 (P04) 2

Figure 8 XRD diffractograms of (Feo, 4i go, 33Mno, ioCuo, ioZno, o6) 3 (P04) 2 ^■ 3H2O and

NH ₄ (Feo, 55mg _0, 45) P04 ^■ 3H ₂ 0th

The solubility tests were carried out in 1 mmol ('rhombus'), 5 mmol (square) citric acid and, in some studies, also in water ('triangle') over a long, well-defined period of time (in hours).

For this purpose, in each case 0.03 g of the respective crystalline orthophosphate were suspended in 30 ml of the respective test liquid (distilled water, 1 mmol / l citric acid and 5 mmol / l citric acid). The suspension was continuously circulated at 25 ° C for 24 hours on a tumble mixer (ECR Nutating Mixer, ECN: 444-0148) (circular + rocking agitation) and then centrifuged to separate the solid residues from the liquid phase. The proportion of dissolved elements P, Fe, Mg, Mn, Cu, Zn, Mo and B in the liquid phase was determined by ICP-OES. The ammonium content was determined by a Hach-Lange cuvette test (LCK test, photometric). Subsequently, the remaining residue was added again with 30 ml of the respective test liquid and continuously circulated until the next analysis time on the tumble mixer. In this way, a saturation effect of the dissolved components in the solvent is avoided.

1 shows the results of Löslichkeitsversuchen 3 (PÜ4) 2 ^* 3 H2O with the specific formula (Feo, 89Mgo, n) 3 (P04) shown 2 ^* 3 H2O with an inventive mixed-metallic crystalline orthophosphate of type (FeMg) wherein the specific formula for this mixed metallic crystalline orthophosphate indicates the molar ratio of iron to magnesium of 89: 1 1. In detail, FIG. 1 shows the time courses of the solubility of the ions P2O5, Fe and Mg contained in the compound.

From the results shown in FIG. 1 it can be deduced that the amount of Mg present here leads to a good solubility of the ions contained in the mixed-metal crystalline orthophosphate according to the invention in 1 mmol citric acid solution and to a very good solubility of the ions in 5 mmol citric acid solution the water solubility of the ions remains negligible.

FIG. 2 shows the results of solubility tests with various mixed-metal crystalline orthophosphates according to the invention of the type (FeMgMnCuZn) 3 (PO 4) 2 ^* 3 h O. wherein the molar ratio of the metals contained in the respective mixed-metallic crystalline orthophosphate varies as shown in detail in FIG. In Figure 2 (FeMgMnCuZn) 3 (P04) ^* 3 the variation of the solubility illustrated 2 H2O based on the Fe ion in water on one side and 1 mmol of citric acid on the other hand for the various inventive mixed-metal crystalline orthophosphates type ,

It can be deduced from the results shown in FIG. 2 that there is a direct correlation between the increase in the proportions of the metals Mn and / or Mg and the increase in the solubility of the ions present in the mixed-metal crystalline orthophosphate according to the invention, the best solubility particularly high levels of Mg is obtained.

3 shows the results of Löslichkeitsversuchen are ^* 3 H2O with the specific formula (Feo, 57Mno, 43) 3 (P0 ₄₎ 2 ^* represented 3 H2O with an inventive mixed-metal crystalline orthophosphate of type (FeMn) 3 (P0 ₄₎ 2, wherein the specific formula for this mixed metallic crystalline orthophosphate indicates the molar ratio of iron to magnesium of 57:43. In detail, FIG. 3 shows the time courses of the solubility of the ions P2O5, Fe and Mg contained in the compound. It can be deduced from the results shown in FIG. 3 that the proportion of Mn present here leads to good solubility of the ions present in the mixed-metal crystalline orthophosphate according to the invention in 1 mmol of citric acid solution, the water solubility of the ions remaining negligible. In Figure 4, the results of Löslichkeitsversuchen with an inventive mixed-metal crystalline orthophosphate type NH ₄ (FeMnMgCuZnMoB) 3 (P0 ₄₎ 2 ^* H20 (having the specific formula NH ₄ Feo, 375Mno, i5Mgo, 25Cuo, io5Zno, o525Moo, o3Bo, o375) 3 (P0 ₄ ) 2 ^* H 2 O, the molar ratio of the metals present in the respective mixed-metal crystalline orthophosphate being represented by the values given in the formula. FIG. 4 shows the time course of the ions P2O5, Fe, Mg, Mn, Cu, Zn, Mo and B contained in the compound for this mixed-metal crystalline orthophosphate.

It can be deduced from the results shown in FIG. 4 that the amounts of Mg and Mn present here lead to good solubility of the ions present in the mixed-metal crystalline orthophosphate according to the invention in 1 mmol of citric acid solution.

FIG. 5 shows the results of solubility experiments with various mixed-metal crystalline orthophosphates of the type NH ₄ (FeMg) (PO ₄ ) ^* H 2 O according to the invention, wherein the molar ratio of the metals contained in the respective mixed-metallic crystalline orthophosphate varies as shown in detail in FIG. In Figure 5 (P04) ^* is the temporal profile of the solubility shown H20 based on the Fe ion in water on one side and 1 mmol of citric acid on the other hand for the various inventive mixed-metal crystalline orthophosphates type NH4 (FeMg).

It can be deduced from the results shown in FIG. 5 that there is a direct relationship between the increase in the proportions of Mg and the increase in the solubility of the ions present in the mixed-metal crystalline orthophosphate according to the invention, even with a fairly low proportion of Mg the described effect is obtained.

FIG. 6 shows the results of solubility tests with various NH4 (FeMnMg) (P04) mixed-metallic crystalline orthophosphates according to the invention, the molar ratio of the metals present in the respective mixed-metallic crystalline orthophosphate varying as shown in detail in FIG , FIG. 6 shows, for the various mixed-metal crystalline orthophosphates of the type NH4 (FeMnMg) (P04) ^* H20 according to the invention, the time course of the solubility based on the Fe ion in water on the one side and in 1 mmol of citric acid solution on the other side. It can be deduced from the results shown in FIG. 6 that there is a direct correlation between the increase in the proportions of the metals Mn and / or Mg and the increase in the solubility of the ions present in the mixed-metal crystalline orthophosphate according to the invention, the best solubility particularly high levels of Mg is obtained.

FIG. 7 shows the results of solubility tests with a mixed metallic orthophosphate of the type NH4 (FeMnMg) (P04) according to the invention with the specific formula NH4Feo, 48Mno, i6Mgo, 36P04) ^* H20, the molar ratio of which in the respective mixed-metallic crystalline orthophosphate metals represented by the values given in the formula. FIG. 7 shows the time course of the ions P2O5, Fe, Mg and Mn contained in the compound for this mixed-metal crystalline orthophosphate.

It can be deduced from the results shown in FIG. 7 that the amounts of Mg and Mn present here lead to good solubility of the ions present in the mixed-metal crystalline orthophosphate according to the invention in 1 mmol of citric acid solution. FIG. 8 shows the XRD diffractograms of two mixed-metal crystalline orthophosphates according to the invention. The top diffractogram derived from an inventive mixed-metal crystalline orthophosphate type FeMgMnCuZn) 3 (P04) 2 having the specific formula (Feo, 4i go, 33Mno, ioCuo, ioZno, o6) 3 (P04) 2 ^■ 3H2O, and the lower diffractogram originates of an inventive mixed-metal crystalline orthophosphate type NH ₄ (FeMg) P04 ^■ 3H ₂ 0 having the specific formula NH ₄ (Feo, 55mg _0, 45) P04 ^■ 3H ₂ 0th

Claims

P a n t a n s p r e c h e

Nutrient composition for plants containing at least one mixed metallic orthophosphate of type [T _a (M1 M2 M3 ... Mx) b (PO 4) _c ^■ n H 2 O], wherein T is selected from NH 4, K or CH 4 N 2 O

 M1, M2, M3 ... Mx are metals selected from Mg, Ca, Mn, Fe, Co, Ni, Cu and Zn,

 a = 0 or 1, where

 ob = 3 if a = 0 and b = 1 if a = 1 and oc = 2 if a = 0 and c = 1 if a = 1 and where - 0 <n <9,

wherein the mixed-metal crystalline orthophosphate contains at least two different metals M1, M2, M3 ... Mx, with the proviso that at least one of these at least two different metals is selected from Mn, Mg and Ca, the total content of Mn, Mg and / or Ca in the total in the range of 0.5 to 90 mol% based on the total amount of all metals contained in the mixed metallic orthophosphate.

A nutrient composition according to claim 1, characterized in that within a period of up to 50 hours at most 10% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0.03 g of the mixed metallic orthophosphate in 30 ml Water at 25 ° C on a tumble mixer continuously circulated.

Nutrient composition according to any one of the preceding claims, characterized in that within a period of up to 100 hours at most 20% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0.03 g of the mixed metallic crystalline orthophosphate is dissolved in 30 ml of water at 25 ° C on a tumble mixer continuously circulated.

Nutrient composition according to any one of the preceding claims, characterized in that within a period of up to 50 hours at least 25% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0.03 g of the mixed metallic orthophosphate in 30 ml 1 mmol citric acid solution at 25 ° C on a tumble mixer continuously circulated. Nutrient composition according to any one of the preceding claims, characterized in that, within a period of up to 100 hours, at least 35% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0.03 g of the mixed metallic crystalline organophosphate is dissolved. thophosphate continuously circulated in 30 ml of 1 mmol citric acid solution at 25 ° C on a tumble mixer.

Nutrient composition according to any one of the preceding claims, characterized in that within a period of up to 50 hours at least 75% by weight of each of the metals contained in the mixed metallic orthophosphate go into solution when 0.03 g of the mixed-metallic crystalline orthophosphate is dissolved. phats in 30 ml of 5 mmol citric acid solution at 25 ° C on a tumble mixer continuously circulated.

Nutrient composition according to any one of the preceding claims, characterized in that the total amount of Mn, Mg and / or Ca in the sum is in the range of 2.5 to 80 mol%, preferably in the range of 5 to 75 mol% the total amount of all metals contained in the mixed metallic orthophosphate.

Nutrient composition according to any one of the preceding claims, characterized in that said at least one mixed-metallic crystalline orthophosphate is of the type [(M1 M2 M3 ... Mx) ₃ (PO ₄ ) 2 ^■ n H ₂ 0], where M1, M2, M3. Mx are selected from Mg, Ca, Mn, Fe, Co, Ni, Cu and Zn, and where 0 <n <9.

Nutritional composition according to any one of the preceding claims, characterized in that the at least one mixed metal crystalline orthophosphate type [T (M1 M2 M3 ... Mx) (P0 ₄₎ ^■ n H2O], where T is selected from NH _4, K, or CH ₄ N 20, wherein M1, M2, M3 ... Mx are selected from Mg, Ca, Mn, Fe, Co, Ni, Cu and Zn, and where n <1.

Nutrient composition according to any one of the preceding claims, characterized in that the nutrient composition contains, in addition to the at least one mixed metallic orthophosphate, further additives selected from macronutrients, micronutrients, multi-nutrient fertilizers, organic fertilizers, plant strengthening agents, chelating and complexing substances or soil conditioner improvers also peat culture substrates, peat-free soils and unit earths. Nutrient composition according to one of the preceding claims, characterized in that the nutrient composition is present in the form of a suspension, a pulverized fertilizer, a granulated fertilizer, in the form of an active-enhanced fertilizer or in the form of a storage fertilizer with a defined slow nutrient release.

Use of a nutrient composition according to one of the preceding claims for the time-controlled release of Mg, Ca, Mn, Fe, Co, Ni, Cu and / or Zn in the rhizodermal region of plants.

Use of a nutrient composition according to any one of the preceding claims for the timed release of Mg, Ca, Mn, Fe, Co, Ni, Cu and / or Zn in the epidermal region of plants.

Method for fertilizing plants, wherein in the method a nutrient composition according to one of the preceding claims is provided in the rhizodermal region of the plants.

A method of fertilizing plants, the method comprising providing a nutrient composition according to any one of the preceding claims in the epidermal region of the plants.

A method of fertilizing plants according to claim 13, wherein in the method the solubility of the at least one mixed metallic crystalline orthophosphate in the nutrient composition in water, 1 mmol citric acid solution and / or 5 mmol citric acid solution is chosen to be that in the at least one mixed metal containing crystalline orthophosphate metals Mg, Ca, Mn, Fe, Co, Ni, Cu and / or Zn are released in the time required for the particular plant and the given conditions amount.