RU2819246C1 - Method of growing spring brown mustard in conditions of leached black soil of western ciscaucasia - Google Patents

Abstract

FIELD: agriculture; agronomy; agrochemistry.

SUBSTANCE: method includes soil treatment by stubble plowing, moldboard plowing to depth of 20–22 cm, autumn leveling, spring harrowing, pre-sowing cultivation, sowing of seeds in early spring period with "physical ripeness" of soil and foliar application of crops in a certain phase of vegetation with complex liquid fertilizers containing zinc and boron in chelate form. Pre-sowing cultivation is carried out at depth of 4 cm. Foliar dressing of crops is carried out in the phase of crop stemming with microfertilizer containing copper sulphate, lithium chloride, ammonium molybdate, potassium hydroxide and chelating agents: amber and citric acids. Weight fraction of nutrients in the working solution of the liquid fertilizer is as follows: succinic acid—70.3 g/l, citric acid—114.2 g/l, potassium hydroxide—120 g/l, zinc—10 g/l, copper sulphate—4.7 g/l, boric acid—35 g/l, ammonium molybdate—3 g/l, lithium chloride—2.8 g/l. Fertilizer application dose is 1 l/ha, and the working fluid consumption is 200 l/ha.

EFFECT: method provides increase in yield and oil content of seeds of spring brown mustard due to increase in vegetative growth and development of plants.

1 cl, 1 tbl, 1 ex

Description

The invention relates to the field of agriculture, in particular to agronomy, agrochemistry, and can be used in growing Sarepta spring mustard.

Mustard is an ancient crop, one of the five main oilseed crops cultivated in the Russian Federation. It is undemanding to soils. On almost all arable soils, a good harvest can be obtained by optimizing the mineral nutrition of mustard plants, both in terms of macroelements (nitrogen, phosphorus, potassium) and microelements (boron, manganese, copper, zinc, cobalt, etc.). A deficiency of nutrients disrupts metabolic processes in the plant’s body, which reduces the yield and quality of products. Only a balanced microelement composition ensures complete physiological processes in plants.

There is a known method of feeding soybean plants, in which microelements are added against the background of the main application of doses of NPK fertilizers (Prosypanov G.S., Zherukov B.Kh. Consumption of nutrients for soybean plants depending on the activity of symbiosis // News of TSKhA No. 4, 1992, p. . 196-202).

The disadvantage of this method is that its implementation requires significant costs for all types of fertilizers and, in addition, the vegetative growth and development of legumes differs from cruciferous crops, which affects the effectiveness of the method.

There is a known method of feeding soybean plants, including the introduction of macro- and microelements in certain phases of development, namely: in the budding - flowering phase against the background of macrofertilizers (nitrogen, phosphorus and potassium), fertilizing is carried out with mineral water with a slightly alkaline reaction in an amount of 250-300 l/ha (RU patent No. 2265306, A01C 21/00, 12/10/2005).

The disadvantage of the known feeding method is that it relates to the cultivation of plants of the legume family, which distinguishes their vegetative growth and development from cruciferous plants - Sarepta mustard, and therefore cannot ensure an increase in mustard yield.

There is a known method for stimulating the growth and development of oilseeds, which includes treating vegetative plants with an aqueous solution of a growth regulator - the drug “Silk”, which is a natural sum of triterpene acids isolated from fir greenery, and the treatment is carried out once or twice during the growing season at a dose of the drug of 1.0 -10.0 g/ha of active substance, in particular, sunflower is treated twice, in the early flowering phase and in the mass flowering phase at a drug dose of 4.0-10.0 g/ha, cotton - once in the budding phase at a drug dose of 5 ,0-7.5 g/ha, rapeseed plants - once in the phase of 5-7 leaves at a dose of the drug 1.0-2.0 g/ha (Patent No. RU 2121272. A01N 65/00, 11/10/1998) .

The disadvantage of this method is that to obtain stable yields of mustard seeds, the use of plant growth regulators is not enough, because Mustard is a complex crop in terms of cultivation technology, and without chemicalization of crop production it is impossible to obtain good yields.

There is a known method of cultivating white mustard on gray forest soils of the Central Non-Black Earth Region, which includes the use of multicomponent liquid fertilizers in a certain phase of plant development, namely in the phase of appearance of 2-4 true leaves and in the budding-flowering phase: Intermag Profi - 1 l/ha; Azotovit, Phosphatovit, RauAktiv - 2 l/ha with a working fluid consumption of 200 l/ha, while winter wheat in its pure form is used as a precursor, then in the spring after autumn plowing, early spring harrowing is carried out to a depth of the arable layer of 20-22 cm, then cultivation to a depth of 10-12 cm, rolling, pre-sowing cultivation to a depth of 2-4 cm and sowing mustard, then re-rolling and, finally, foliar feeding, and harvesting is carried out when the seeds are fully ripe (Patent RU No. 2739440, A01G 22/00 , A01C 21/00, publ. 12/24/2020). The disadvantage of this method is its ineffectiveness for Sarepta spring mustard, whose vegetative growth and development are not the same as white mustard.

There is also a known method of foliar cultivation of white mustard for seeds in the southern part of the Non-Chernozem zone of Russia (on gray forest soils), characterized by the fact that soil cultivation is carried out by peeling stubble to a depth of 12-14 cm, autumn plowing to a depth of 20-22 cm, spring harrowing, cultivation and rolling with smooth water-filled rollers, and pre-sowing cultivation is carried out to a depth of 2-4 cm at a seeding rate of 2.5 million pcs/ha or 12 kg/ha of viable seeds, the plants are brought to the phase of leaf rosette and budding, after which foliar feeding with complex liquid fertilizers ACTIVE-Boron - 1 l/ha (with a mass fraction of nutrients, not less than: nitrogen (N) 50 g/l, boron (B) 133 g/l) and ACTIVE-Zinc - 1 l/ha (with a mass fraction of nutrients: nitrogen (N) 65 g/l, phosphorus (P) 25 g/l, sulfur 70 g/l, zinc 142 g/l with a working fluid consumption rate of 200 l/ha.

In this case, herbicidal treatment is carried out with Galion - 0.3 l/ha with a working fluid consumption rate of 200 l/ha, and in the period from germination to the appearance of four true leaves - treatment with the Fastak insecticide 0.1 l/ha with a working fluid consumption rate of 250 l/ha. We took this method (Patent RU No. 2751599, A01C 21/00; C05D 9/02, published 07/15/2021, Bulletin No. 20) as a prototype.

The disadvantage of the prototype is the ineffectiveness of the method for Sarepta mustard due to the fact that foliar fertilizing is carried out twice during the plant growing phase, which is an irrational use of fertilizers on Sarepta spring mustard crops, especially in the butanization-flowering phase, because During this phase, the process of redistribution of plant dry matter between the vegetative and generative parts comes to an end, which is why microfertilizers have less effect on crop productivity, i.e. on the yield and oil content of seeds.

The technical result of the proposed method is an increase in the yield and oil content of Sarepta spring mustard seeds by increasing the vegetative growth and development of plants.

The technical result is achieved by the fact that in the known method of growing mustard, including soil cultivation by peeling stubble, plowing to a depth of 20-22 cm, autumn leveling, spring harrowing, pre-sowing cultivation to a depth of 4 cm, sowing seeds in early spring at “physical ripeness” soil and foliar feeding of crops in a certain phase of the growing season with complex liquid fertilizers containing zinc and boron in chelated form, according to the invention, foliar feeding of crops is carried out in the stemming phase of the crop with microfertilizer containing salts of microelements: zinc, copper (in the form of sulfates) and chelating agents: succinic and citric acids, as well as microfertilizers: potassium hydroxide, lithium chloride, boric acid, ammonium molybdate, while the proportion of nutrients in the working solution of liquid fertilizer is:

succinic acid 70.3 g/l Lemon acid 114.2 g/l Potassium hydroxide 120 g/l Zinc 10 g/l, Copper sulfate 4.7 g/l Boric acid 35 g/l Ammonium molybdate 3 g/l Lithium chloride 2.8 g/l,

in this case, the dose of fertilizer is 1 l/ha, and the flow rate of working fluid is 200 l/ha.

Examining the level of technology in the process of conducting a patent search for all types of information publicly available in the press, we did not identify technical solutions that have essential features of the proposed method regarding the conditions for carrying out actions, namely the modes of their implementation: the processing phase, the substances used for complex liquid fertilizers, mass fraction of substances in the working solution, the rate of consumption of the working fluid.

A method has been identified to increase the resistance of grape plants to biotic and abiotic stresses, which is a system of treating vegetative plants by spraying solutions of complex microelement fertilizers of the same composition in chelated form with a multiplicity of 3-6 times with small amounts from 0.5 to 1.3 l/ha and increasing by 10-20% in each subsequent treatment with application rates in accordance with the dynamics of growth of leaf mass, while treatments are carried out at intervals of no more than 6-8 days and combined with treatments with fungicides and insecticides (Patent RU No. 2735624, A01G 13/00, 17/02, 7/00, 2019).

This technical solution is of interest only because of the use of complex microelement fertilizers in chelate form. However, the known technical solution provides for repeated treatments up to 6 times during the growing season of grape plants in fractional doses, increasing with each new treatment as the plant develops and at intervals of 8-10 days between sprayings, which is not suitable for mustard crops.

Thus, the claimed technical solution meets the patentability criteria of “NOVELTY” and “INVENTIONAL LEVEL”. The claimed technical solution also meets the patentability criterion “INDUSTRIAL APPLICABILITY”, because it can be used in agriculture, and the essence of the proposed technical solution is sufficiently disclosed in the description of the invention.

Our research on the issue of increasing the yield and oil content of Sarepta spring mustard, grown on leached chernozem of the Western Ciscaucasia, was based on the task of identifying the optimal supply of Sarepta spring mustard plants with nutrients at all stages of growth and development in order to identify the most sensitive phase of development of plants of this crop to deficiency nutrients when grown in chernozem conditions leached by foliar (leaf) feeding with complex liquid fertilizers. Foliar feeding (treatment) is not the main one, but only adds and adjusts the amount of essential minerals that are in the soil. With a lack of boron, flowering is delayed and few seeds are formed in the pod. Molybdenum deficiency reduces the frost and drought resistance of plants, and the formation of proteins decreases. With a lack of copper, the leaves curl, wither and die. With a lack of zinc, the drought and winter hardiness of plants decreases, they are susceptible to fungal and bacterial diseases. The deficiency of one of the elements of mineral nutrition cannot be replaced by an excess of another, therefore it is necessary to provide plants with optimal nutritional elements at all stages of growth and development, which can be achieved by foliar (leaf) feeding with complex liquid fertilizers.

To identify the optimal phase of the growing season of Sarepta spring mustard plants for foliar feeding with microfertilizers, when the process of redistribution of plant dry matter between the vegetative and generative parts is maximum, as well as the optimal doses of microelements for foliar feeding in this phase, an agrochemical examination of the soil of the experimental plot was carried out. The studies were carried out at the central experimental base of the Federal State Budgetary Institution Federal Scientific Center VNIIMK (Krasnodar). The soil of the experimental plot is represented by leached chernozem. An agrochemical examination of the soil of an experimental plot with an area of 150 ^m2 was carried out along a pre-designed route (along two diagonals); soil samples were taken using a soil drill before sowing Sarepta mustard to a depth of arable layer (An) of 0-20 cm. The following agrochemical analyzes of soil were carried out samples. Humus was determined using the method of A.V. Tyurin. modified by V.N. Simakova. Nitrate nitrogen was determined by the ionometric method according to GOST 26951-86, ammonium nitrogen by the colorimetric method with Nessler's reagent. An extract for determining phosphorus and potassium in a soil sample was prepared according to the Machigin method modified by TsINAO (GOST 26205-91). Microelements boron and molybdenum were determined according to GOST ISO 22036-2014, zinc - according to GOST R 5068694, copper - according to GOST R 50683-94. Analysis to determine the oil content of seeds was carried out according to GOST 8.597-2010 in the laboratory of biochemistry of the Federal State Budgetary Institution Federal Scientific Center VNIIMK.

According to an agrochemical examination of leached chernozem, the humus content corresponds to a low level (3.4%), phosphorus to an average level (21 mg/kg), potassium to a high level (313 mg/kg), which corresponds to classes III and IV of agrochemical availability, respectively. The content of mineral nitrogen (N-NO ₃ +N-NH ₄ ) is sufficient (14.2 mg/kg). Also in the soil layer (0-20 cm) a low content of microelements was observed: boron (B) - 0.26 mg/kg and molybdenum (Mo) - 0.14 mg/kg, which indicates the need for additional fertilizing of Sarepta mustard plants in the stemming phase to obtain high crop yields.

EXAMPLE.

The main tillage for Sarepta mustard was carried out in a manner generally accepted for this soil-climatic zone for spring crops. Immediately after harvesting the previous crop (cereals), the stubble was peeled to a depth of 6-8 cm and moldboard plowed to a depth of 20-22 cm, followed by leveling and cultivation as the weeds grew. In the spring, in experiments before sowing mustard, spring harrowing was carried out to a depth of 3 cm with a deviation of no more than 1 cm. Pre-sowing cultivation - to a depth of 4 cm upon the onset of “physical ripeness” of the soil. The object of study is Sarepta spring mustard variety Juno. The seeding rate was 1.7 million units/ha. Seeds were sown to a depth of 2-3 cm with a row spacing of 30 cm. Sowing was carried out in the first ten days of May in 2021, and in 2022 - in the second ten days of April. Spraying of crops with chelated fertilizer was carried out using a sprayer.

It was revealed: spraying Sarepta spring mustard crops with a complex microfertilizer in the claimed composition during the stemming phase contributed to an increase in yield, oil collection and oil content of seeds.

The invention is illustrated by the table:

Productivity, oil content of seeds and harvest of Sarepta spring mustard oil depending on the microfertilizers used in the claimed composition

According to the table, foliar feeding of Sarepta spring mustard crops with complex microfertilizer in the claimed composition contributed to a significant increase in yield by 0.49 t/ha, and seed oil content by 1.4% compared to the option without treatment with complex microfertilizer.

Thus, the claimed set of essential features of the proposed method of growing Sarepta spring mustard in the leached black soil conditions of Western Ciscaucasia is necessary and sufficient to achieve the technical result specified above.

Claims (3)

A method of growing Sarepta spring mustard in leached chernozem conditions of Western Ciscaucasia, including soil cultivation by stubble peeling, moldboard plowing to a depth of 20-22 cm, autumn leveling, spring harrowing, pre-sowing cultivation, sowing seeds in early spring when the soil is “physically ripe” and foliar feeding of crops in a certain phase of the growing season with complex liquid fertilizers containing zinc and boron in chelated form, characterized in that pre-sowing cultivation is carried out to a depth of 4 cm, foliar feeding of crops is carried out in the stemming phase of the crop with microfertilizer containing copper sulfate, lithium chloride, ammonium molybdate , potassium hydroxide and chelating agents: succinic and citric acids, while the mass fraction of nutrients in the working solution of liquid fertilizer is: succinic acid 70.3 g/l Lemon acid 114.2 g/l Potassium hydroxide 120 g/l Zinc 10 g/l Copper sulfate 4.7 g/l Boric acid 35 g/l Ammonium molybdate 3 g/l Lithium chloride 2.8 g/l, in this case, the dose of fertilizer is 1 l/ha, and the flow rate of working fluid is 200 l/ha.