UA124179C2 - METHOD OF RESTORATION AND INCREASE OF SOIL FERTILITY ON THE PRINCIPLE OF BIORREGULATION IN MICROBOTS AND MYCOCENOSES - Google Patents

Abstract

The invention relates to a method of restoring and increasing soil fertility on the principle of bioregulation in microbial and mycocenoses, in which first determine the micromycetic composition of the soil and using bioindication determine the composition of microbiota that forms this soil type, and then make the soil biochar saturated with mycorrhizal fungus Tuber melanosporum IMBF-100106 in the composition of the drug "Mikovital" in the amount of 15-75% and phosphate-mobilizing, nitrifying and nitrogen-fixing bacteria, depending on the needs of plants and micromycetic composition of the soil.

Description

(54) METHOD OF RESTORATION AND INCREASE OF SOIL FERTILITY ACCORDING TO THE PRINCIPLE OF BIOREGULATION IN

MICROBOT AND MYCOCENOSES (57) Abstract:

The invention relates to a method of restoring and increasing soil fertility based on the principle of bioregulation in microbial and mycocenoses, in which the micromycete composition of the soil is first determined and, with the help of bioindication, the composition of the microbiota that forms this type of soil is determined, and then a biochar saturated with mycorrhizal fungi is introduced into the soil Tybeg teiapozrogyt IMVE-100106 in the composition of the drug "Mikovital" in the amount of 15-7595 and phosphate-mobilizing, nitrifying and nitrogen-fixing bacteria, depending on the needs of the plants and the micromycete composition of the soil.

The invention belongs to the fields of agriculture and forestry, and also relates to the restoration of soils damaged by mining. The invention relates to the technology of regenerative land use through the use of ecological biotechnology, which is based on the processes of bioregulation by terrestrial ecosystems through the restoration of the microbial and fungal structure of soils.

The technology involves its application in the restoration of lands disturbed by human economic activity with the aim of restoring soil fertility and obtaining high yields.

There is a known method of increasing soil fertility, in which phosphorus-containing raw materials are added to the soil together with an acidifying additive. Phosphorite flour is used as a phosphorus-containing raw material. Phosphogypsum is used as an acidifying additive. The ratio of components in the proposed mixture is 1:1. The use of the invention allows to increase the yield of agricultural crops (KO Mo 2178964, publ. 10.02.2002).

The disadvantage of this method is the mandatory humus content of more than C 95 in the soil of the treated area.

There is a known method of soil treatment, in which the soil is treated by mulching with peat crumb, pre-mixed with calcium compounds. According to the invention, ammonium lignosulfonate is additionally added to the peat in the amount of 0.02-0.5 95 wt. based on the completely dry substance, followed by mixing. Calcium carbonate is used as a calcium compound. (Ko Mo 2067804, publ. 10/20/1996).

The disadvantage of this method is the mandatory presence of organic matter in the soil of the cultivated area to ensure the vitality of the cultivated culture, which is excluded in the conditions of desert sands.

There is a known method of soil enrichment, in which a sub-peat layer of sapropel with a high content of organic matter is introduced into the soil.

The technical result of the invention is an increase in the content of organic matter in the soil, an increase in the content of useful microflora, an improvement of the ecological situation in the soil itself due to an increase in the content of mineral nutrition elements (KO Mo 2408181, published: 10.01.2011).

The disadvantage of the method is the mandatory presence of organic matter in the soil of the treated area for

To ensure the vitality of cultivated culture.

A known method of restoring and increasing soil fertility, which involves tilling or mulching the soil with mulch containing ecologically clean agro-ore with high sanitary, hygienic and nutritional properties of natural origin - zeolite-containing raw materials, bird droppings, by-products of agricultural crops, sawmill and grain production waste . Consumption of the mixture is 8-10 t/ha. The application of the invention allows to improve the agrophysical and agrochemical properties of the soil (KO 2199193, published on February 27, 2003).

The disadvantage of the method is the use of bird droppings without its prior disinfection, which introduces pathogenic microflora into the soil, such as helminths, and there is also no guaranteed "mechanism" of starting the starting conditions for the development of microbiocenosis and, accordingly, there are no guarantees of restoring and maintaining the fertility of such soils.

From the state of the art, no technical solution similar to the one claimed has been found.

The invention is based on the task of creating a method of restoring and increasing soil fertility, in which, thanks to the provision of starting conditions for the development of microbiocenosis in the soil and the formation of humus, it is possible to obtain high yields at lower costs than when using traditional mineral or organic fertilizers.

The technical result is achieved by the fact that as a result of the application of the proposed biotechnological method of restoring harmonious and clearly balanced living conditions of mycobiota and microbiota in the soil, mycorrhiza is formed in it, which contributes to the formation of a balanced microbial community in the zone of plant roots and productive growth of plants and the expansion of the fertile layer.

The task is solved by the fact that in the method of restoring and increasing soil fertility according to the principle of bioregulation in microbial and mycocenoses, the micromycete composition of the soil is first determined, and with the help of bioindication, the composition of the microbiota that forms this type of soil is determined, and then a biochar saturated with mycorrhiza is introduced into the soil with the fungus Tybeg teiIapozrogyt51223 (Tybeg teiIapozrogyt IMV E-100106) in the composition of the drug "Mykovital" in the amount (15-75 95) and phosphate-mobilizing, nitrifying and nitrogen-fixing bacteria, depending on the needs of plants and the micromycete composition of the soil.

Bioregulation of the process is due to the use of the ascomycete strain Tybeg teiapozrogyt U5 1223 (Tybeg teI(apozrogyt IMV E-100106), which forms a mycorrhiza, is responsible for the exchange of carbon and phosphorus between the soil and the plant, promotes carbon deposition and active photosynthesis.

Exudation of trehalose mushroom mycelium ensures colonization of plants with the necessary microorganisms. If microorganisms are destroyed as a result of human economic activity, their active strains saturate the biochar together with Tibreg teiYiapozrogyt. Research on the use of mushroom-enriched (on the example of the preparation from the vegetative cells of the black truffle "Mykovital" (Patent for the utility model Mo 111174 "Complex biologically active preparation for regulating the development and growth of plants based on the suspension of mycorrhizal fungi "Mykovital"). Research in the field of saturation with microorganisms biochar in the practice of bioregulation of disturbed soil ecosystems indicate its unique property of positively influencing the processes of interaction of microorganisms and plants in the histosphere, rhizoplane, rhizosphere and throughout the entire territory of application of the strain Tybreg teiapozrogyt IMV E-100106. Mycorrhiza, which is formed as a result of the use of the drug, promotes formation of a balanced microbial community in the zone of plant roots and productive growth of plants. We have developed and successfully implemented biotechnology for restoring harmonious and well-balanced living conditions of mycobiota and microbiota in soil in disturbed soil ecosystems after extracting useful burning, the use of pesticides and toxic chemicals in the cultivation of agricultural products and deforestation.

All life on earth is a way of transforming carbon compounds. The use of biochar (coal from plant organic matter) to restore soil fertility is allowed in

Europe since 2013. It is applied both in its pure form and as part of organic fertilizers. The resins formed during the production of biochar have a high capacity for ion exchange. That is, the ion of any substance easily attaches to them and then is not washed away even by rain. However, it can be assimilated by the roots of plants or hyphae of mycorrhizal fungi. Numerous bacteria living on plant roots secrete enzymes capable of dissolving soil minerals. The ions formed at the same time quickly attach to the solidified resin of charcoal, and plants can "remove" these ions from the coal with their roots as needed, i.e. feed them. In addition, many substances necessary for plants fall into the soil with rains, and this is also a considerable amount. There is especially a lot of nitrogen in the rains, which is also not washed out of the soil, but is captured by charcoal. As a result, such soil is able to feed all plants by itself, without any fertilizers. An increase in the yield of crops and an increase in the fertile layer has been proven in

From the course of numerous scientific experiments. The main feature of biochar is its porous structure. The large surface area of these pores allows a large number of microorganisms to settle in it. Colonization by microorganisms occurs most often during the composting process.

For a better effect, coal is crushed and worms, eating it together with organic matter, populate the pores with useful microorganisms of their intestinal microflora. In addition, biochar retains moisture and nutrients, which allows microorganisms to survive in adverse conditions and then quickly develop and spread in the soil. This effect was used to improve the process of mycorrhiza development on degraded soils, as well as to introduce microorganisms necessary for certain purposes. We suggest using biochar, the carbon content of which is not less than 85-92 95.

An example of using the method

This technology provides for the gradual (within 1-3 years) restoration of the soil during the transition from intensive to biological land use and involves the application of the principles of regenerative land use. The technology of regenerative land use is based on the knowledge of the processes that occur in the plant and in the soil during its growing season.

In the spring, when the vegetation process begins, the plant secretes exudates into the rhizosphere, the basis of which are sugars, in order for the mycorrhizal fungus to start growing and functioning. Effective growth and functioning of mycorrhiza begins. It releases trehalose into the environment - a disaccharide that is synthesized in the cells of many fungi and enters the environment of the mycorrhizosphere and rhizosphere of the plant as part of mycelial exudates. It is believed that trehalose is one of the factors that determine the composition of bacterial communities (I2!ytinN. eia!., 2006;

Wow75. eiaI,, 2007|. The long-term practice of using the mycorrhizal preparation for plant growth and development "Mycovital" indicates a number of regularities and perfectly explains the principles of symbiotic plant-fungus-bacterium relations. Research indicates that the mycorrhizal fungus Tybeg teiapozrogyt M51223 (Tyreg teiapozrogyt IMV E-100106) is the key in the triple plant-fungus-bacterium symbiosis. This fact is of crucial importance for the restoration of soils and the creation of an effective technology for its regeneration. The first stage of the proposed method of bioregulation is the study of the micromycete composition of the soil. To assess the quality of the environment for plant development, the method of bioindication using soil micromycetes was used.

Bioindication is a method of determining the quality of the habitat of organisms based on species composition and quantitative development of bioindicator species and the structure of their communities.

We use the method of serial dilutions and direct sowing on agarized media of soil suspensions, as well as sequence analysis of the soil. Analysis of soil mycobiota is carried out using methods of quantitative ecology.

The grouping as a system is characterized by the interaction between the species that are part of it. In the microbial community, the interaction between species is determined primarily by trophic (food) relationships. Determination of the ratio of species in the studied soil indicates the content of nutrients in the soil, their composition and the availability of the main nutrients for the plant. During the analysis, we determine the indicators, enter them in the table. 1, and we also carry out statistical processing of data on the micromycete composition of soils, identifying key species in correlation pleiads and dendrograms of group similarity. The main groups of microorganisms include:

A. Oligotrophs - a group of fungi that are satisfied with low concentrations of nutrients;

B. Chemolitoautotrophs - use the energy of mineral compounds to fix carbon dioxide and microbial biomass;

B. Zymogenic group of fungi - decomposes fresh organic remains;

D. Autochthonous group - decomposes humic substances.

Table 1

The number of propagules is 1.

Name of soil samples (CFU) Pathogens. "Main GROUPS

Standard 180x102 Standard 3-5 95 microorganisms

Explanation to the table: By sowing soil suspensions on nutrient media, we obtain the species composition of the studied soil samples, as well as the number of fungal propagules in one gram of soil. Their approximate norm is 180x107 colony-forming organisms.

Next, we determine the species composition and number of pathogenic and toxin-producing mushrooms (in the table we enter the name of the species - pathogens, toxin-producing and calculate their percentage).

The next stage of work is the determination of the main groups of microorganisms:

The determination is made using the methods of molecular ecology, which is based on the principle of studying the biodiversity of microorganisms using the analysis of individual elements from genetic material, namely sequence analysis: extraction from the soil of nucleic acids (DNA,

RNA) followed by amplification of 165 rRNA gene fragments using the polymerase chain reaction and study of the amplified fragments by molecular genetic methods.

The results of the sequence analysis indicate the presence of the main groups of microorganisms. Its generalized data are included in the table.

Next, we analyze the indicators of the extensive chemical analysis of the soil (mechanical composition, presence of macro- and microelements). Combining the results of both analyzes makes it possible to understand whether there are enough microorganisms for the chemical elements and compounds contained in a specific soil sample (type) to reach the plant. The analysis also indicates the number and species composition of pathogenic and toxin-producing micromycetes.

Depending on the results of the correlation analysis, we determine those species in the soil near the plant that are the cause of allelopathy. We select antagonistic species among biological, microbiological and mycological preparations registered and certified by the Organic Standard, which will displace pathogens and toxin-producing agents and contribute to the restoration of the plant-fungus-bacterium triple symbiosis and effective plant growth.

The next stage of bioregulation involves the introduction of the mycorrhizal fungus Tybreg teIapozrogyt

U51223 (Tybeg teIapozrogyt IMV E-100106) in the composition of the preparation "Mikovital" and other microbial and fungal preparations necessary for the restoration of a specific soil. The application is carried out by the method of saturating the biochar with biological preparations selected as a result of the study of correlations between species of microorganisms and fungi. To do this, we saturate the biochar with black truffle mycorrhizae and other microbiological preparations depending on the needs of the soil, taking into account its composition and the natural conditions of the region. The saturation technology does not matter. Biochar, saturated with mycorrhizae or microorganisms, will be used both in its pure form and as part of various fertilizers.

The process of saturation and introduction of biochar:

A. One liter of "Mikovital" is diluted in nine liters of non-chlorinated water heated to 18 "C, into which bacterial preparations are added in the required proportion for this specific soil.

B. We saturate the biochar with the resulting tank mixture for 40-60 minutes. (depending on its composition and pore size). The process is carried out at a temperature of 18-25 "C without direct sunlight.

B. The resulting substrate is applied to the trunk circle near trees and bushes, burying it in the soil to a depth of 10-15 cm. The amount of applied substrate depends on the age of the plant. On the fields that were treated with pesticides and toxic chemicals, on the territory after deforestation or mining, and on other disturbed territories, we apply the prepared substrate to the entire area of the territory. The amount of biochar saturated with fungi and microorganisms is determined individually.

Table 2

The influence of "Mikovital" on the fertility of agricultural crops

The rate of consumption of the drug

Nutrition, .

K Processing l/ha (consumption Period (phase) Results of application of ultura planting application during . - working hours on different crops of material, vegetation of solution 500 l l/ha)

One seed treatment was carried out before planting. Received

And to the phase of the 3rd | following results: increase

Soybeans 1 l/t 11.5 trefoil yield by 3-5 times, vegetable fat content by 1.7 Fo-1.9 to protein content by 2.9-3.2 95

Seed processing was carried out. An increase in yield by 2.5-2.8 was obtained

To the phase of the 5th and .

Corn 1 l/t 1-1.5 leaves at a time due to an increase in the number of corn cobs and the number of grains in the beginning

Seeds were processed. Obtained: an increase in the density and height of plants

Wheat 0.5 l/t 1-1.5 To the tillering phase!| respectively by 6.7-4.6 times.

Yield increased by 13.7 times, protein content in grain increased by 2.4 times

Seeds were processed. Received: barley increase in plant density and height ' 0.5 l/t 1-1.5 Before the bushing phase!| respectively by 7.2-5.3 times. rye village .

Yield increased by 15.5 times, protein content in grain increased by 1.9 times

Seeds were processed. Received:

And increasing the size of the baskets (radius

Sunflower 1 l/t 1-1.5 To phase 4-6 - | increased by 3-5 cm), the number of grains of real leaves. in baskets increased by 30 95,

Increase in fat content by 1.8-2.6 95

Seeds were processed. Received:

In the early phases of increasing the number of pods by 15 95,

Peas 1 l/t 1-1.5 R increase of peas in a pod for 3-4 development. we pcs. As a result, the yield increased by 15.8 95 plant development 1.5 lna

Potatoes per hectare 1-15 Up to 15-20 cm Potato tubers were processed. 10 to 12 kg of potato tubers were obtained from a bush

Table 2

The influence of "Mikovital" on the fertility of agricultural crops

The rate of consumption of the drug

Nutrition, .

Processing l/ha (consumption) Period (phase) Application results

Culture |

The seeds were treated before germination and the root system

Top dressing before planting in the ground. The size and weight of the pepper increased to 700-200 ml per plant after and brob

Pepper 10 l of rooting water after 800 g, compared to untreated. 1-1.5 plants 300-500 gr. The increase of licorice per 1500 harvest system was 21.6 95. plants of drip: - .

Feeding plants after rooting irrigation through the drip irrigation system gave an increase in yield by 25.7 95 and ensured plant health

Fertilizing plants after seedling processing: 200 ml per seedling, or J

We received an increase in yield by 13.9 95.10 liters of seedling water. : y

Tomatoes 1-1.5: an increase in the content of carbohydrates by 12.8- per 1500 rootings due to o : : 13.5 95, mono- and disaccharides per 8.6- plants by the drip irrigation system 9.4 95

After germination, or 200 ml for rooting

Cucumbers 10 liters of water 145 seedlings through | Seedlings were processed:

P per 1000th system Received an increase in yield by 21.9 95 drip irrigation plants

The root system was treated

Existing plants before planting. plantings We got 100 95 survival rate of all plants applied, increase in annual growth. 2-55 solution! root, through |by 25-50 95, increase of the root

Nut, 1lnadbdl and 2. M . Hazelnuts WATER (depending on the system of the system in 5-10 times, the growth of the productivity of undu d age) of drip | up to 25-37 95, the mass of one fruit of irrigation, or for| increased by 13 95, the yield per tree by 18 95, the yield of kernels of the applicator increased by 7.2-7.9 95, the fat content by 2.9-3.7 Uo

The root system was processed

On existing plants or plantings before planting, it was introduced under the root of 3-4 year old plants. dkah We received 100 95 survivability of all inputs under . . 2-5 95 root solution, or through plants, increasing annual growth

Apple tree, 1lnadl . ' by 23-37 95, an increase in the root (depending on the system 2. M . pear water and the system in 7-10 times, the growth of the yield of the age) drip irrigation: up to 25-32 95, an increase in the mass of the fruits of irrigation, or by irrigation and up to 15-20 95, increasing the content of the application. of carbohydrates by 13.2-14.7 90, vitamins by

P 12.3-12.7 95, trace elements at 17.2-18.0 95

Table 2

The influence of "Mikovital" on the fertility of agricultural crops

Nutrition, i

K Processing l/ha (consumption Period (phase) Results of the application of ultur |precipitation during different cultures of the material, working vegetation P result of a solution of 500 l/ha

Processing of the root system was carried out. before planting plants or gardens, it was applied under the root of 2-4 year old plants. introduction under We received 1 0О 95 survival rate of all 2-5 95 root solution, or through Plants, increase in annual growth

Peach T1Ilnabdl » resolution, Rez on 21-31 95, increase of root ' (depending on the system; 2. M . plum water age) drip system by 1-10 times, growth of irrigation yield, or for up to 26-33 9b, increase weight of fruits with help up to 17-21, increasing the content of the applicator of carbohydrates by 15.2-16.7 90, vitamins by 14.3-14.7 95, trace elements by 15.2-19.0 96

The root system was treated before planting currants and gooseberries, and a mycorrhizal preparation was applied through the drip irrigation system for blueberries, strawberries, blackberries, strawberries, and blueberries.

We received for currants - a yield increase of 12.6-14.7 95.

An increase in the root system in 4-10

Currant times. . gooseberry ' All plants were healthy during the blackberry harvest. Through the system of the entire growing season, for pokhin T1Ilnabdl 1.5-2 95 drop gooseberry - crop increase 1552-11 6.68 9o. blueberry water irrigation solution For blackberry, blueberry, blueberry, strawberry, strawberry strawberry, organic strawberry 'technology based on mycorrhization was developed.

The application of technologies gave the following results: an increase in annual growth by 15 95-18 95, yield increases from 15.9 to 21 95, the yield of one bush increased by 17.7 Fo-18.6 95, the quality of fruits improved, their tasting evaluation increased from 3.6 to 4.8

All data are presented as mean values

Table 2

The influence of "Mikovital" on the fertility of agricultural crops

The rate of consumption of the drug

Feeding.

Processing d "| Period (phase) l/ha (consumption and Results of application

Culture |

The root system was treated before planting, and a mycorrhizal preparation was applied under the soil. root using the applicator:

On the existing o. -. Received 9-year-old oak plantations,

Coniferous trees and ET plantings. 2-5 96 solution. by 2.5-3 meters higher than deciduous 1lnadl and introduction under and and (depending on: non-mycorrhized plantings, received for species of water: root for SC, . age) b-year term industrial wood, trees with help -: planting coniferous and leafy applicator: tree species on devastated lands are used as a method of phytoremediation and phytoremediation of disturbed lands

Decorative! О0.5 liOl On existing //|Application on medicinal herbs gives flowers and water on 1.5-2 95 plantings 100 95 grafting of plants on new medicinal 800-1000 solution application under |territories and ensures high quality of grass plants roots of herbs

The application of the above-described method of restoring and increasing soil fertility with the use of a biochar saturated with vegetative cells of the mycorrhizal fungus Tybeg teiIapozrogyt U51223 and the necessary bacteria will completely restore the fertile soil layer according to 1-

Since the year and will increase the fertility of agricultural crops by 25-30 95.

Claims (1)

FORMULA OF THE INVENTION A method of restoring and increasing soil fertility based on the principle of bioregulation in microbial and mycocenoses, in which the micromycete composition of the soil is first determined and, with the help of bioindication, the composition of the microbiota that forms this type of soil is determined, and then a biochar saturated with the mycorrhizal fungus Tyreg is introduced into the soil te/apozorogit IMVE-100106 in the composition of the preparation "Mikovital" in the amount of 15-75 95 and phosphate-mobilizing, nitrifying and nitrogen-fixing bacteria, depending on the needs of the plants and the micromycete composition of the soil.