RU2789878C1 - Method for folow fertilization in soybean and rapse growing - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to the field of agriculture. A method for foliar top dressing in the cultivation of soybeans and rapeseed is proposed, according to which fertilizer is applied, seeds are sown, and foliar top dressing is carried out. At the same time, spring pre-sowing treatment is carried out with the application of mineral fertilizers to the soil at a dose of N₆₀P₆₀K₆₀and at the same time fertilizers are applied in the form of nitrogen phosphate with an NPK ratio of 16:16:16, seeds are sown and two foliar top dressings of vegetative plants are carried out. The first top dressing - in the branching phase for soybeans and in the rosette phase for rapeseed, and the second top dressing, with an interval of two weeks, is carried out for two vegetative plants in the budding phase - the beginning of flowering. Foliar top dressing is carried out with water-soluble microfertilizers Lebozol-Bor and Revetaplant + NMgS, which includes magnesium.

EFFECT: invention provides an increase in the yield of soybeans and rapeseed.

4 cl, 2 dwg, 3 tbl

Description

The invention relates to agriculture, in particular to the cultivation of soybean and spring rapeseed using fertilizers for foliar (foliar) feeding of agricultural plants containing water-soluble microfertilizers to increase the yield of these crops.

Currently, in agriculture there is a problem of providing plants of various origins with nutrients during the growing season. This problem is usually solved by using mineral fertilizers.

It is known that plants are able to absorb nutrients not only by the root system, but also by the surface of the leaf. This type of processing is called foliar top dressing. Processing the leaf surface of plants with aqueous solutions of macro- and microfertilizers improves the photosynthetic activity of plants, creates favorable conditions for their growth and development, increases productivity by 15-18%, and increases resistance to adverse environmental factors.

Foliar fertilizing with microfertilizers improves vegetative growth and development of plants, increases yield and quality of the products obtained.

Soybean and rapeseed marginal crops and their cultivation can be seen as an investment platform with a future development perspective. Soy as a crop is grown from the Far East to the northern regions of the Non-Chernozem Zone and the Kaliningrad Region. Along with the expansion of sown areas, there is a growing interest in the technology of cultivating these crops. In particular, to the nutritional regime of growing soybeans and rapeseed.

It should be noted that soybeans and, like other legumes, have an increased removal of boron and molybdenum. In this regard, scientists are faced with the task of improving and optimizing the methods of using microfertilizers in soybean cultivation. In addition, soybeans are highly demanding on soil fertility and mineral nutrition conditions. Culture nutrition is differentiated by the phases of growth and development. The assimilation of nutrients in the initial phases is weak, since the root system is not able to provide the plant with them sufficiently. During this period, it consumes about 10% of nutrients and needs easily digestible forms of fertilizer. The main part (90%) is consumed by soybeans during the period of crop formation - from the beginning of flowering, which in the conditions of the Central Black Earth region falls at the end of June and up to full ripening. The most important nutrients at the beginning of development are trace elements N, P, K. At the next stage of development, the consumption of all nutrients increases and reaches its maximum by the time of flowering and formation of pods. Among the trace elements, soybean plants need zinc, boron, molybdenum, cobalt and manganese the most.

Trace elements are actively involved in the processes of assimilation of microelements, which makes it possible to balance the nutritional regime of the plant and distribute biochemical processes among organs during certain critical periods of vegetation.

The effectiveness of the use of single-component microfertilizers for soybean and rapeseed has been studied by many authors.

A good alternative to single-component microfertilizers for feeding vegetative soybean and rapeseed plants can be multicomponent microfertilizers. Therefore, it is of practical interest to study the effectiveness of this technique on the content of photosynthesis pigments, i.e. a source of energy for the products of plant photosynthesis, which is created by the energy of the sun. Unlike macronutrients - nitrogen, phosphorus, potassium, the removal of which with the harvest of agricultural crops amounts to hundreds of kilograms per hectare, the consumption of microelements is much lower, from several grams to several hundred grams.

The composition and ratio of microelements are selected taking into account the individual needs of a particular culture.

Nitrogen is the main biogenic element, it is part of the protein and nucleic acids. Nitrogen is part of such vital substances as amino acids, chlorophyll, phosphatides, as well as organic compounds such as alkaloids, glycosides, etc. The mineral forms of nitrogen that enter plants go through a complex cycle of transformations, eventually being included in the composition of organic compounds.

Zinc affects the metabolism in plants and their growth, which is due to its content in more than 30 enzymes. With a lack of zinc, reducing sugars accumulate, and the content of sucrose and starch decreases, the accumulation of organic acids increases, the content of auxin decreases, and protein synthesis is disturbed. With zinc starvation, non-protein soluble compounds, amitosis, and amino acids accumulate. Its deficiency manifests itself, first of all, on acidic, strongly podzolized soils. Zinc fertilizers are used when the content of this element is less than 0.2-1 mg per 1 kg of soil.

Zinc trace elements are introduced into foliar microfertilizers, both in the form of salts and in the form of chelate complexes with various complexes.

As a result of the patent information study, the following patents and sources of information were selected. It should be noted that the following examples and test data allow a better understanding of individual specific embodiments of the invention. It is implied that the examples do not limit the scope of the invention disclosed in this description. For a specialist in this field of knowledge should be obvious the possibility of implementing various variants of the described concept.

A known method of soybean cultivation, including harvesting the predecessor, applying organic fertilizers at a dose of 20-25 t/ha and complete mineral fertilizer at the rate of N _30-45 , P _60-90 , K _45-60 to obtain 2 t/ha of grain, the introduction of trace elements of molybdenum and boron during joint pre-sowing treatment with their inoculation with soybean razotorphin, basic tillage to a depth of 0.24 m, pre-sowing tillage: cultivation to a depth of 6-8 cm and before sowing to a depth of 3-5 cm to create a seed bed, leveling, application soil herbicides, sowing seeds of soybeans of the 1st or 2nd class of the sowing standard of the 1-5th reproduction with a row spacing of 0.15; 0.45; 0.60 and 0.70 m to a depth of 3-4 cm, soybean crop care, soybean pest and disease control, vegetative irrigation, harvesting and post-harvest grain processing (see the book Crop production of the Central Black Earth region. Edited by Fedotov V .A. and others - Voronezh: Center for the Spiritual Revival of the Chernozem Territory, 1988. - S. 186-191).

The disadvantages of the described technology of cultivating soybeans for grain, despite the use of molybdenum (Mo) and boron (B) microelements, include the low quality of grain due to the lack of microelements during flowering and fruiting.

A known method of cultivating soybeans for grain in irrigated agriculture, including stubble cultivation of the predecessor, soil treatment with a herbicide, fertilization, plowing with a layer turnover, early spring loosening of the soil and cultivation, pre-sowing irrigation and cultivation to a depth of 4-5 cm, rolling the soil before and after sowing , harrowing seedlings, irrigation during the growing season, desiccation of crops and harvesting (see Soybean cultivation technology: recommendations of Federal State Scientific Institution "RosNII PM" - Novocherkassk: Helikon LLC, 2007, - 28 p.).

The disadvantages of the described method, despite the possibility of maintaining the irrigation regime and the NPK maintenance regime, include low grain quality in terms of microelement content, low fat content in soybean seeds and limited yield.

A complex microfertilizer for foliar feeding of plants is known, which contains a composition of microelements and other chemicals: sulfate salts of gallium, iron, indium, cadmium, cobalt, manganese, copper, tin, silver, cesium, zinc, nitrate salts, bismuth, mercury, lead, thallium, potassium bromide, iodide, arsenic acid, selenite acid, telluric acid, chromic acid, antimony trichloride, ammonium molybdate, as well as nitric, boric, chloroauric acid and water (Patent RU 2238924, C05D 9/02 dated 27.10.2004).

The use of this fertilizer increases the immunity of plants to diseases and resistance to adverse conditions. At the same time, it is assumed that the whole mass of micro- and macroelements applied to it (26 ingredients) should be absorbed by plants. However, scientific research has established that the assimilation of exogenous substances, namely, micro- and macroelements introduced from the outside, depends on the endogenous biochemical processes of the object. Therefore, to create a rational system of mineral nutrition, an increase in the number of ingredients and an increase in the concentration of substances cannot be justified from the point of view of plant physiology and is not advisable from an environmental and economic point of view. Also, a rational system of mineral nutrition does not provide for the obligatory use of mineral fertilizers on soils that do not have a deficiency of micro- and macroelements.

A means for foliar feeding of crops is known, containing a composition of trace elements in the form of copper, zinc, boron, iron, molybdenum, and manganese and a composition of trace elements in the form of nitrogen, magnesium and sulfur (Patent RU No. 2377227, C05D 9/02 dated 27.12.2009) .

This product contains cobalt, chromium, selenium, nickel, lithium and potassium, with the following content of ingredients (in wt.%): total nitrogen (0.49±0.1)), manganese (0.29±0.01), copper (0.64±0.01), zinc (1.36±0.1), boron (0.15±0.5), magnesium (0.89±0.05), iron (0.4± 0.01), molybdenum (0.44±0.002), sulfur (5.05±0.001), cobalt (0.084±0.001), potassium (0.06±0.002) - 15 ingredients in total.

At the same time, trace elements zinc, copper, nickel, iron and cobalt are presented in a chelated form.

The known agent is a nutrient mixture for the treatment of vegetative plants of agricultural crops and provides an increase in crop yields, acceleration of the plant growth process and improvement of the quality of agricultural products not only by providing the plant with nutrients, but also solves the problem of their absorption, by activating internal biochemical processes.

This effect is achieved due to the fact that, in comparison with similar products and fertilizers containing various compositions of micro- and macroelements, the composition and number of elements of this product are selected taking into account their electrochemical characteristics in contact with biochemical processes.

To achieve the expected effect, this agent is recommended to be used on grain crops three times in the tillering, bobbing and milky ripeness phases, i.е. for feeding the plant during the entire period of its development, as a fertilizer.

However, with a rational approach to stimulating the growth and fruiting of cultivated plants at different stages of its development, a differentiated approach is needed to the use of means that allow correcting its condition, taking into account and depending on changes in exogenous factors. Repeated use of a known means may be redundant or insufficient to obtain a sustainable end result. In particular, the repeated use of this agent on soils that do not have a deficiency of microelements is not rational, in terms of increasing soil fertility, and excessive, in terms of enhancing biochemical processes.

A known method of increasing the oil content of soybean seeds, which consists in the presowing treatment of soybean seeds with an aqueous solution of the growth regulator Melafon. The use of Melafon at a concentration of 1⋅10 ^-4 -1⋅10 ^-9 g/l leads to an increase in the energy of germination and seed germination, yield and oil content in the seeds of the crop (Patent RU No. 2390984, А01С 1/00 dated 10.06.2010).

The disadvantage of this method is the decrease in yield due to the deterioration of symbiotic nitrogen fixation due to the lack of additional treatment of soybean seeds with rhizotorphin.

A known method includes moisturizing, languishing and separating soybean seeds. Humidification is done by soaking in water for 2-30 minutes, languishing for at least 10 minutes. until the end of seed swelling. Separation is carried out in saline solution followed by drying. The method allows to improve the quality of seed material by separating damaged, feeble, and unripe soybean seeds (Patent RU No. 2132120, A01C 1/00 dated 27.06.1999). However, this method is quite traumatic for seeds, since during soaking followed by languishing, the integrity of the seed coat will be violated, which will further lead to injury to the seeds during sowing.

The closest in technical essence to the claimed method is, adopted as a prototype, a method of soybean cultivation using a full-component fertilizer "BIOPLANT FLORA", which consists in pre-sowing seed treatment, sowing, foliar feeding. Pre-sowing seed treatment is carried out with Rezotdin mixed with Bioplant Flora multicomponent fertilizer at a dose of 1 l/t and foliar feeding of plants, which is carried out with Bioplant Flora multicomponent fertilizer in the 4-5 leaf phase and at the end of bean formation at a dose of 0.25-1.0 l/ ha (Patent RU No. 2482659, A01G 1/00, A01C 1/00, A01N 63/00, C05G 1/00, C05F 11/08 dated 05/27/2013).

The disadvantage of this method is the low quality of seed treatment, since the soybean seed coat is quite hard and short-term application of solutions does not allow the polycomponent fertilizer to fully affect the physiological processes occurring in the seeds, which affects the seedlings. In addition, foliar top dressing is carried out twice during the growing season, which is not economically feasible, since the costs of this agrotechnical measure are not compensated by an increase in yield. In addition, the method does not disclose the use of foliar top dressings with water-soluble modern microfertilizers as fertilizers given in the description below, containing active substances much higher than in known analogues - substances that improve absorption, i.e. increasing the absorbent properties of the leaf, as well as determining the effect of foliar fertilizing with fertilizers on the biometric indicators of soybeans and spring rapeseed; Establishing the features of soybean yield formation when using foliar top dressing with micronutrient fertilizers.

The technical result of the invention is to increase the yield of soybeans and spring rapeseed by increasing field germination, stimulating symbiotic activity through treatment with multicomponent microfertilizers.

The technical result obtained is an increase in the yield of agricultural crops and an improvement in quality with the use of modern microfertilizers due to the maximum prolongation of nutrition during the growing season.

The technical result is achieved by the fact that in the method of foliar top dressing when growing soybeans and rapeseed, according to which fertilizer is applied, seeds are sown, foliar top dressing, according to the invention, spring pre-sowing treatment is carried out with the application of mineral fertilizers to the soil at a dose of N ₆₀ P ₆₀ K ₆₀ , and at the same time, fertilizers are applied in the form of nitrogen phosphate with a ratio of NPK 16:16:16, seeds are sown, then two foliar top dressings of vegetative plants are carried out, the first top dressing is in the branching phase for soybeans and in the rosette phase for rapeseed, and the second top dressing, with an interval of two weeks, carried out for two vegetative plants in the phase of budding - the beginning of flowering, while foliar top dressing is carried out with water-soluble microfertilizers Lebozol-Bor and Revetaplant + NMgS, which includes magnesium.

In addition, soybeans are additionally treated with Glyfoshans herbicide, EC at a dose of 1.0 l/ha, and for spring rapeseed, Galera herbicide, EC at a dose of 0.3 l/ha, is used in the period of 4-6 real rapeseed leaves, moreover, spraying vegetative weeds for soybeans with Glyfoshans is carried out at the end of summer or in autumn in the post-harvest period, before soybean sowing.

In addition, additional treatment is carried out against rodents and sucking pests with the insecticide Imidoshans plus, SC at a dose of 0.15 l/ha, and vegetative plants are harvested when the seeds are fully ripe.

In addition, soybeans are sown with a seeding rate of 400 thousand grains / ha, and rapeseed is sown with a seeding rate of 2.0 million grains / ha, to a planting depth of 5 cm, while the depth of two vegetative plants is carried out in a continuous way, row spacing is 15 cm , according to the predecessor - early potatoes.

A comparative analysis of the proposed technical solution, in comparison with the prototype, on leached chernozem soils allows us to conclude that the claimed method of non-fodder feeding of soybeans and spring rapeseed with the proposed various microfertilizers during the growing season, as water-soluble microfertilizers, can balance the nutritional regime of the plant and distribute biochemical processes by organs, during certain critical periods of vegetation. Culture nutrition is differentiated by the phases of growth and development. The treatment of plants with these fertilizers made it possible to form a better assimilation apparatus, which, as a result, contributed to a more intensive use of photosynthesis for the creation of biomass and plant productivity. According to the content, which, below, large studies have been carried out for foliar feeding, where the degree of their assimilation is quite high.

Based on this, it can be concluded that the claimed invention complies with the criterion of patentability "inventive step".

The claimed technical solution meets the criterion of patentability "industrial applicability", because can be used in agriculture.

The object of the study is the Prudence soybean variety and the Reef spring rapeseed variety.

Soybean varieties Prudence high-yielding. The variety has been included in the State Register of Breeding Achievements since 2012. The plants are tall, up to 90 cm. The protein content in the seeds is 34-38%, the fat content in the seeds is 16-20%. The weight of 1000 grains is 250 grams. Sowing time - the soil warmed up to 12-14°C. Spring rapeseed of the Reef variety is distinguished by high productivity and quality of oil seeds, resistant to major diseases. Since 2013, it has been included in the State Register of protected varieties approved for use in production.

Characteristics of water-soluble microfertilizers studied in the experiment.

Lebozol-Bor is a series of new generation fertilizers, including preparations for foliar feeding, and it is optimally distributed on the surface of the leaves, increases their absorbent properties, attracts moisture and, in general, becomes a long-lasting active source of nutrition, moreover, it is resistant to rain washing off.

Miscibility: Can be mixed with common plant protection products.

Revitaplant Legumes + NMgS is a complex liquid fertilizer in a chelated form intended for foliar feeding of legumes with an increased content of nitrogen, magnesium and sulfur.

An example of the implementation of the method.

The experiments were carried out in the conditions of the experimental field of the Yerevan State University. I.A. Bunin, Lipetsk region in 2019-2021

The soil of the experimental plot is leached chernozem, which represents the following agrochemical characteristics of the arable layer: heavy loamy granulometric composition with pH 5.5-5.6, humus content 5.8-5.9%, total content of exchangeable potassium 112-114 mg/kg, mobile phosphorus 148-151 mg/kg.

Records and observations during the growing season were carried out on the basis of the "Methodology for conducting field agrotechnical experiments with oilseeds" /Krasnodar, 2010 - 327 p./. Mathematical processing of the results was performed according to B.A. Armor "Methodology of field experience (with the basics of static processing of research results)" textbook for higher agricultural institutions. stereotype. Ed., add. And recycled. 1985 M.: Alliance, 2014-351 p.

The control field experiment was laid on a site leveled by fertility. The area of the plot size is 30 m ² , respectively, the accounting area is 20 m ² .

Climatic weather conditions 2019-2021 were characterized by positive for development, so the SCC in 2019 - 0.98; in 2020 - 1.28; in 2021 - 1.03. These weather conditions are shown (Fig. 1).

The predecessor of soybean and spring rapeseed was early potato.

Mineral fertilizers N ₆₀ P ₆₀ K ₆₀ were applied as a fertilizer for the crop before the pre-sowing spring treatment, and at the same time they were applied in the form of azofoska with an NPK ratio of 16:16:16.

As a treatment of soybean and spring rapeseed plants, a double foliar top dressing with microfertilizers was used. The treatment of plants with fertilizer solutions at a concentration of 0.5% was carried out in accordance with the general recommendations for cereals and oilseeds with an interval of two weeks.

Thus, water-soluble microfertilizers Lebozol-Boro and Revitaplant Legumes + NMgS were used for the study: the first treatment was carried out in the branching phase for soybean and the beginning of rosette formation - for rapeseed, and the second was carried out at an interval of two weeks for both cultures in the budding phase - the beginning of flowering . The layout of the experience is built according to the method of organized repetitions. Repetition 4-fold.

Experience scheme: 1. Control (without treatment); 2. Lebozol-Bor at a dose of 1 l/ha; 3. Revitaplant Legumes + NMgS at a dose of 2 l/ha; 4. Lebozol-Bor + Revitaplant Legumes + NMgS with drug consumption rate, respectively: 1 l/ha; 2 l/ha.

Protection of soybeans from weeds was carried out mechanically, in the process of growing the fight against pea weevil and aphids, the insecticide Dishans, EC, was used at a dose of 1.0 l/ha. To protect spring rapeseed plants, the herbicide Galera, EC, was used at a dose of 0.3 l/ha. To control a complex of rodents and sucking pests, including hidden ones, we used the insecticide Imidoshans plus, SC at a dose of 0.15 l/ha.

Studied in the experiment, the relative content of chlorophyll a and b, as well as carotenoids in the leaves, was carried out using a KFK-5M spectrophotometer in accordance with the method of V.F. Gavrilenko.

Harvesting was carried out without preliminary desiccation, manually simultaneously from the entire experimental plot, followed by drying for three days.

The photosynthetic productivity of plants was determined by the efficiency of light energy conversion in chloroplasts, the rate of formation of photosynthetic metabolites and their use for growth processes and biosynthesis of secondary compounds.

Chlorophyll is the most important photocatalyst, its deficiency limits the rate of photosynthesis.

The microfertilizers studied in the experiment contributed to the formation of a pigment complex in soybean leaves during the phases of branching and budding - the beginning of flowering, which indicates the presence of a response of the pigment system of the assimilation apparatus of soybean to foliar feeding with multicomponent microfertilizers (table 1).

An increased effect of foliar top dressing in the field for photosynthetic activity was obtained in those variants where Revitaplant Legumes + NMgS was used in its pure form, as well as in a mixture with fertilizers in the form of Lebozol + NMgS, which additionally included magnesium and which fulfilled the need plants in this trace element.

Thus, the conducted studies made it possible to establish a positive effect to prevent the premature destruction of chlorophyll and reduce the aging process of plants. This moment is very important in the technology of cultivation of soybean and spring rapeseed, which makes it possible to take into account bad weather conditions and then proceed during the harvesting of the crop.

The treatment of plants with these fertilizers (preparations) made it possible to form a better assimilation apparatus and, as a result, contributed to a more intensive use of photosynthesis products for the creation of biomass and plant productivity.

During the research, measurements of the height of the studied soybean variety "Prudens" were carried out. It was found that in the experiment for three years of research on variants, the height varied from 95.2 to 105.3 cm, while the number of lateral branches and the height of attachment of the lower bean were determined.

Table 2 shows the effect of top dressing on the elements of the yield structure for soybeans.

Table 2 shows that foliar feeding with multicomponent micronutrient fertilizers (preparations) has a significant impact on the growth and development of soybean plants.

The tallest plants were formed in the Lebozol-Bor + Revitaplant Legumes + NMgS variant and averaged 105.3 cm in plant height, which is 10 cm higher compared to the control. An increase in the total height of plants increased, respectively, the number of lateral branches.

As a result of the experiment, it was found that the height of attachment of the lower bean for soybeans is an important technological feature, directly proportional to the loss of yield during harvesting, i.e. the higher on the stem the bean is attached, the less crop loss will be.

In variant two and three (Table 2), the difference in this trait was not significant and amounted to 0.4 cm. In the variant Lebozol-Bor + Revitaplant Legumes + NMgS, attachment of the lower beans was noted at the level of 12 cm, which is noticeably higher compared to the control by 2.8 cm.

When conducting research on the structure of the yield of the spring rapeseed variety Reef and soybean variety Prudence, it was found that their dependence on the treatment of foliar dressings significantly stimulated an increase in seed yield (Fig. 2).

The results obtained testify to the high efficiency of the proposed method for foliar application of multicomponent microfertilizers on plants with uniform coverage of the applied microfertilizers throughout the plant leaf plate, increased adhesion of liquid fertilizers to the leaf surface, and resistance to washing off by rain and dew.

Therefore, it can be noted with certainty that foliar feeding of plants in terms of yield showed on the variant with a combination of paired (joint) application of Lebozol-Bor + Revitaplant Legumes + NMgS with a double treatment with an interval between it of two weeks for 2 plant cultures. And the yield was 1.26 t/ha.

When applying fertilizers individually as foliar top dressing, high yields were noted in the variant with the use of Revitaplant Legumes + NMgS, the yield was 1.22 t/ha.

The correlation coefficient between the leaf surface area in different phases and soybean yield in the fruiting phase is close r=0.99±0.242, and determination d _yx =r ² =0.98), which indicates a large relationship between soybean yield and pigment content in the studied options.

All methods of applying microfertilizers increased this indicator in comparison with the control. When harvesting soybean, the attachment height of the bottom bean is of great importance. The amount of losses of soybean seeds directly depends on this indicator.

The maximum yield of the spring rapeseed variety was found in the variant with the action of Lebozol-Bor + Revitaplant Legumes + NMgS and amounted to - 1.7 t/ha, which is +0.36 t/ha higher compared to the control.

It should be noted that a high effect is associated with fertilizers due to the elimination of nutrient deficiency throughout the growing season, an increase in the assimilation apparatus and a higher formation of chlorophyll and an increase in plant stress resistance.

Thus, we state that foliar feeding of soybean and spring rapeseed plants through the use of microfertilizers is an actual requirement of today, which can increase productivity and improve their cultivation, and also allows us to recommend this soybean variety and spring rapeseed variety for implementation on chernozems of leached soils of the forest-steppe .

Claims (4)

1. The method of foliar top dressing when growing soybeans and rapeseed, according to which fertilization is carried out, sowing seeds, fodder top dressing, characterized in that spring pre-sowing treatment is carried out with the application of mineral fertilizers to the soil at a dose of N ₆₀ P ₆₀ K ₆₀ and at the same time applied in the form azotophos with an NPK ratio of 16:16:16 fertilizers, sow the seeds, then carry out two foliar top dressings of vegetative plants, the first top dressing - in the branching phase for soybeans and in the rosette phase for rapeseed, and the second top dressing, with an interval of two weeks, is carried out for two vegetative plants in the budding phase - the beginning of flowering, while foliar top dressing is carried out with water-soluble microfertilizers Lebozol-Bor and Revetaplant + NMgS, which includes magnesium. 2. The method according to p. 1, characterized in that weeds are additionally treated for soybeans with Glyfoshans herbicide, EC at a dose of 1.0 l/ha, and for spring rapeseed Galera herbicide, EC at a dose of 0.3 l/ha, is used, in the period of 4-6 real leaves of rapeseed, and spraying vegetative weeds under soybean with Glyfoshans is carried out at the end of summer or in autumn in the post-harvest period, before soybean sowing. 3. The method according to claim 1, characterized in that additional treatment is carried out against rodents and sucking pests with the insecticide Imidoshans Plus, SC at a dose of 0.15 l/ha, and vegetative plants are harvested when the seeds are fully ripe. 4. The method according to claim 1, characterized in that soybeans are sown with a seeding rate of 400 thousand grains/ha, and rapeseed is sown with a seeding rate of 2.0 million grains/ha at a planting depth of 5 cm, while the depth of two vegetative plants is carried out in a continuous way, with a row spacing of 15 cm, according to the predecessor - early potatoes.

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