RU2811689C1 - Composition for increasing growth, development of plants and quality of agricultural products - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to regulators of plant growth and development. The composition for increasing the growth, development of plants and the quality of agricultural products contains the following per 1 kg of composition, g/kg: orthocresoxyacetic acid triethanol ammonium salt — 90÷110; magnesium nitrate — 225÷275; potassium nitrate — 180÷220; monopotassium phosphate — 135÷156; manganese chelate — 27÷33; zinc chelate — 67÷83; copper chelate — 67÷83; iron chelate — 90÷110; boric acid — 13÷17; ammonium molybdate — 3÷7. The composition is a crystalline powder.

EFFECT: proposed composition for increasing the growth, development of plants and the quality of agricultural products provides increased yield and quality of products, increased seed germination, increased absorption of microelements by plants at the cellular level, reduced agrochemical load on the soil, reduced content of heavy metals in products, reduced damage to plants by fungal diseases and pests, increasing the shelf life of agricultural crops treated during the growing season, obtaining environmentally friendly products.

1 cl, 17 tbl, 3 ex

Description

The invention relates to the field of agriculture, namely to plant growth regulators (PGR), which is a preparation that contains a complex of nutrients necessary for plants (salts of inorganic acids, complex organic compounds), taken in optimal proportions, taking into account the agrochemical characteristics of the crops grown , and can be used for pre-sowing treatment of seeds (planting material) and spraying of agricultural crops.

The following solutions are known from the prior art.

A known composition for processing agricultural crops, including the plant growth and development regulator "Silk" and fertilizer for greenhouses "Rastvorin" (RU 2184451 C1, 07/10/2002), as well as a composition for increasing the growth, development and quality of agricultural crops, including an aqueous solution of synthetic analogues of natural phytohormones Mival and Krezacin (RU 2116728 C1, publication date 08/10/1998).

A composition for increasing the growth, development and quality of agricultural crops is also known, including an aqueous solution of synthetic analogues of natural phytohormones Mival, Krezacin and fertilizer for greenhouses “Rastvorin” (RU 2427134 C1, publication date 08/27/2011).

Also known is a composition for increasing the adaptability and productivity of spring wheat, used in the pre-sowing preparation of seeds during early spring sowing in the Baikal region, containing preparations, wt. %, PVA (polyvinyl acetate) 20-4.0; Krezacin 0.20-0.012; Terpensil 0.40-0.002 with the additional inclusion of the microelement zinc salt ZnSO4 in an amount of 0.03-0.003 wt. %, the rest water up to 100% (RU 2430500 C2, publication date 10.10.2011).

The closest analogue of the patented composition is a composition for increasing the growth and development of agricultural crops, containing an aqueous solution of synthetic analogues of natural phytohormones Silacin and Krezacin, as well as the fertilizer Kufecin and the wetting solubilizer polyethylene glycol PEG-1500 with the following content of initial components per 1 liter: Silacin (1- chloromethylsilatrane) 5-25 mg, Krezacin (orthocresoxyacetic acid triethanolamine salt) 80-100 mg, Kufecin (Cu, Fe, Zn) 10-30 ml, wetting agent solubilizer polyethylene glycol (PEG-1500) 5-25 mg (RU 2760163 C1, date publications 11/22/2021).

The common disadvantages of the known compositions are: low increase in crop yields, short shelf life of the resulting agricultural products and the need for additional treatments of the resulting products with various chemical plant protection agents, which reduces its environmental purity, high incidence of crops with various fungal diseases, high susceptibility to pests in the initial phases of the growing season , lack or excess of macro and microelements (RU 2760163 C1, RU 2184451 C1), or deficiency of synthetic analogues of natural phytohormones (RU 2427134 C1, RU 2430500 C2).

The technical problem was the need to create a universal product that does not have phytotoxicity, but is highly effective for the main types of agricultural crops and provides high membrane-penetrating ability and stimulation of plant growth at the cellular level, inhibition of lipid peroxidation in the cell membrane, as well as increasing the stability of x crops to extreme temperatures (drought, frost) or sudden changes in weather conditions.

The technical result is an increase in productivity and quality of products, due to increased seed germination, more complete absorption of microelements by plants at the cellular level, reduction of agrochemical load on the soil, reduction of the content of heavy metals in products, elimination of shortage or excess of macro and microelements, reduction of damage to plants by fungal diseases and pests, increasing the shelf life of agricultural crops treated during the growing season while simultaneously obtaining high-quality environmentally friendly products.

The claimed technical result is achieved due to the composition of the composition for increasing the growth, development of plants and the quality of agricultural products, which is a crystalline powder containing orthocresoxyacetic acid triethanolammonium salt, magnesium nitrate, potassium nitrate, monopotassium phosphate, boric acid, ammonium molybdate, as well as manganese chelates, zinc, copper and iron, with the following content of components per 1 kg of composition, g/kg:

orthocresoxyacetic acid triethanolammonium salt 90÷10 magnesium nitrate 225÷275 potassium nitrate 180÷220 monopotassium phosphate 135÷156 manganese chelate 27÷33 zinc chelate 67÷83 copper chelate 67÷83 iron chelate 90÷110 boric acid 13÷17 ammonium molybdate 3÷7

Due to the increase in productivity and the increase in the removal of various elements from the soil, the role of microelements has significantly increased. Copper, manganese, zinc, boron, magnesium and others are catalysts for many enzymatic processes in the plant cell, improve metabolism and have a positive effect on the yield and quality of grain. They are used for pre-sowing seed treatment and foliar feeding.

There are two circumstances that determine the inclusion of microelements in the nutrition system: the first is a decrease in their entry into the soil, the second is intensive cultivation technologies. Previously, the need for microelements was satisfied by adding humus and mineral macrofertilizers. Now the application of organic fertilizers has sharply decreased, and highly concentrated mineral fertilizers do not contain microelements. Therefore, there was a need to apply microfertilizers. Microelements cannot be replaced by other nutrients.

In the presence of the required amount of microelements, plants synthesize a full range of enzymes, allowing more intensive use of energy, water, and nutrients to form high yields. Microelements contribute to the development of a powerful branched root system, which ensures more complete absorption of nutrients from the soil by plants. The resistance of plants to drought, cold, and disease increases. The most important microelements for winter wheat are manganese, copper, iron, and zinc.

Magnesium is part of chlorophyll, phytin and other substances. Potatoes, beets and legumes are in great need of it. It is most often lacking in acidic soils of light mechanical composition and poor in humus. A valuable source of replenishing magnesium in the soil are some potassium-magnesium salts (potassium magnesium and kainite), as well as organic fertilizers. The proposed composition uses magnesium nitrate in an amount of 225÷275 g/kg.

Boron promotes photosynthesis, carbohydrate and protein metabolism. It improves the oxygen supply to the plant's root system through the formation of peroxides. Boron increases the activity of enzymes, increases the hydrophilicity of protoplasm colloids, plays an important role in fertilization, fruiting and in the development of stem growth points. The proposed composition uses boric acid in an amount of 13÷17 g/kg, with a lack of boron, plant growth slows down, weak flowering is observed without the formation of ovaries, growth points die off, plant resistance to disease decreases, the disease “heart rot” appears in beets, flax is affected bacteriosis. The application of boron fertilizers eliminates these phenomena and increases crop yields. Boron is found not only in special boron fertilizers, but also in other fertilizers, for example, in ash, manure, and partly in phosphorus fertilizers.

Ammonium molybdate acid promotes the absorption of nitrogen, increases the yield of legumes, vegetables, root crops, buckwheat, flax, etc. Both its deficiency in the composition and its excess (more and less than the limits of the declared range) have a detrimental effect on the processed plant.

Copper enhances protein and carbohydrate metabolism, improves plant respiration, increases their resistance to certain fungal diseases, and activates the activity of B vitamins. The proposed composition uses copper chelate in an amount of 67÷83 g/kg. When the amount of copper chelate is less than 67 g/kg, plants do not form seeds.

Manganese is a component of enzymes and some proteins. It promotes the formation of chlorophyll, plant respiration and the accumulation of sugars in them.

Zinc plays an important role in plant respiration. It is necessary during the development of the embryo and affects the formation of chlorophyll and growth substances. The proposed composition uses zinc chelate in an amount of 67÷83 g/kg. With a lack of this nutrient, white or light green chlorotic spots appear on the leaves, and small leaves are observed. This phenomenon is eliminated by adding a small dose of zinc sulfate or other its salts to the soil.

Iron is necessary in the composition as a supplier of microelements to plant cells for better absorption. The proposed composition uses iron chelate in an amount of 67÷83 g/kg. When the iron chelate content is less than 67 g/kg, the absorption of other microelements is not carried out.

Potassium stimulates the normal course of photosynthesis, regulates the opening and closing of stomata and, therefore, regulates the absorption of CO2. Due to the fact that it promotes the accumulation of carbohydrates in plant cells, potassium increases the osmotic pressure of cell sap and thereby increases the cold resistance and frost resistance of plants. Potassium is absorbed by plants in the form of cations and in this form remains in the cells, activating the most important biochemical processes in plant cells; potassium increases their resistance to various diseases, both during the growing season and in the post-harvest period. Plays an important role in the regulation of water in plants (osmoregulation). Both in the absorption of water through the roots of plants and in the release through stomata. It also improves drought resistance. Potassium plays an important role in the activation of many enzymes associated with plant growth. Plants also require potassium for the synthesis of protein and starch. It is necessary at almost every stage of protein synthesis. In the synthesis of starch, the enzyme responsible for the process is activated by potassium.

The proposed composition contains orthocresoxyacetic acid triethanol ammonium salt - an analogue of the plant phytohormone - auxin, which functions as a powerful anti-stress agent and significantly reduces the period of plant adaptation to the effects of unfavorable natural and man-made factors. The principle of operation of the drug is high membrane-penetrating ability and stimulation at the cellular level, which allows the use of low concentrations of the drug. The penetrating ability of one of the components makes it possible to enhance the penetration of all substances necessary for the development of the plant, used in the technology of growing products, i.e. serves as a catalyst.

The proposed composition has the following actions.

Antioxidant: the drug inhibits lipid peroxidation in the cell membrane.

Adaptogenic: increases the resistance of agricultural crops to extreme temperatures (drought, frost) or sudden changes in weather conditions.

Fungicidal: significantly increases plant resistance to fungal and viral diseases, as well as the effectiveness of protection against septoria, leaf rust, olive mold, powdery mildew, root rot, etc.

It is used in conjunction with fungicides during pre-sowing seed treatment or in combination with planned foliar treatments. Fits perfectly into existing agrochemical methods of agricultural production.

Application of it:

- increases seed germination energy

- promotes the early formation of a powerful root system, accelerates the formation of the tillering node,

- helps increase the number of productive stems by 1-2

- significantly improves the overwintering of winter crops.

- significantly mitigates the burden of pesticide stress

- helps to overcome return frosts, prolonged spring cold snaps, and prolongation of the grain filling phase in dry times

- activates the plant’s consumption of minerals, the macro- and microelements included in the complex are absorbed faster by plants, which is especially important during critical periods of development, and prevents micronutrient deficiency.

The composition is used as follows:

Seed treatment is carried out by dressing in dressing machines or by soaking in special containers.

Treatment of plants is carried out by spraying plants using boom, fan, and backpack sprayers.

The working solution is prepared immediately before treatment. The sprayer tank is filled 1/3 with water, with the mixing device running, the required amount of the drug is added (according to the instructions for use given in Table 1), water is added to the calculated amount, the solution is mixed and the plants are treated.

When soaking seeds, the solution is prepared directly in soaking containers.

The proposed composition is compatible with most pesticides used, with the exception of highly alkaline ones. Compatibility testing is required before use. The effect of the composition appears after 12-20 hours (when processing seeds) or after 4-5 days (seedlings, seedlings). The period of protective action is 30-60 days after treatment.

The solution is further illustrated with specific application examples.

Example 1.

The object of the study is winter wheat of the domestic selection Moskovskaya-40 of the super-elite category. The study determined the effect of treating seeds and plants with the claimed composition on the growth and development of winter wheat, the dates of the onset of phenological phases and the duration of interphase periods, as well as taking into account the effect of treating seeds and plants on the level of yield and its structure, as well as on grain quality indicators.

The work was carried out in the fields of the agriculture department of the Tula Research Institute of Agriculture - a branch of the Federal Research Center "Nemchinovka" on deeply leached medium-loamy, medium-humus chernozem, typical for the region.

Agricultural technology for cultivating winter wheat was generally accepted. The predecessor of winter is black fallow.

Sowing in all variants was carried out with treated seeds using CH-16. Chemical weeding - using an OP-200 sprayer or manually using a backpack sprayer. Mathematical data processing was carried out using the method of variance analysis (Dospehov B.A., 1985).

Phenological observations.

They were carried out in accordance with the “Instructions for hydrometeorological stations and posts.” In all variants of the experiment, the dates of the mass onset of plant development phases were noted: sowing, shoots, third leaf of tillering, cessation of growing season, resumption of growing season, emergence into a tube, appearance of the lower node of the straw above the soil surface, heading, flowering, milky ripeness, waxy ripeness, full ripeness . Determination of soil moisture was carried out instrumentally every 10 cm to a meter depth on 8 days every ten days (until the waxy ripeness of the grain). The condition of the winter crop was assessed on a five-point scale (5 - excellent, ... 1 - bad).

Analysis of the phytosanitary state of agrocenosis.

According to the main phases of development in each variant, starting from the appearance of the lower straw node, the presence of pests and the degree of damage to the crop by them were noted.

At the beginning and end of the growing season, in all variants, the degree of damage to wheat by root rot was determined.

Determination of the main elements of the crop structure.

Before harvesting, in all variants of the experiment, the following was determined: the total mass of the above-ground part of the plant per 1 m ² , the number of productive stems, the length of the ear, the number of spikelets in the ear, the weight of the ear, the weight of 1000 grains, the nature of the grain was determined, the proportion of grain in the total above-ground mass and in the ear . Plants for analysis were cut at waxy ripeness at soil level.

Harvest accounting.

A continuous plot was carried out using a Winterschteiger combine. The registration area of the plot is 40 ^m2 . The harvest was calculated using standard humidity and 100% purity.

Determination of grain quality.

The protein and gluten content in grain was determined using generally accepted methods.

Table 2. Scheme of the experiment to study the effect of the claimed composition on winter wheat Moskovskaya 40.

Seeding rate - 300 kg/ha;

Area of 1 unit is 80 sq.m;

Repeat the experiment 3 times;

area for option 1 80*3=240 ^m2 .

Contents of components in the composition:

orthocresoxyacetic acid triethanolammonium salt 90 g/kg magnesium nitrate 275 g/kg potassium nitrate 180 g/kg monopotassium phosphate 135 g/kg manganese chelate 33 g/kg zinc chelate 83 g/kg copper chelate 83 g/kg iron chelate 105 g/kg boric acid 13 g/kg ammonium molybdate 3 g/kg

Research results

To establish the relationship between the growth and development of winter wheat plants, analyzes were made at the end of autumn, during the booting phase and when the lower straw node appeared. In all replicates, 10 typical plants were selected and the following were determined: the development phase of winter wheat, bushiness of plants, their average height, weight, length and weight of the root system. Dry autumn delayed the growth and development of winter wheat, so the first analysis of plants in the experiment was carried out at the beginning of the winter period. All plants were in the “3rd leaf” phase. Their average height in the control variant was 8.4 cm (from the soil surface to the end of the longest leaf), seed treatment before sowing with the declared composition increased the figure by 0.7 cm, The weight of 1 plant in the variant with seed treatment with the declared composition was 0 .2308 g, control - 0.2136 g (Table 5). During the spring inspection of winter wheat sowing of plants in the booting phase, their height was on control - 9.3 cm (from the soil surface to the bend of the top leaf). The use of the claimed composition with microfertilizers increased the height of the plants to 11.9 cm. The weight of one plant was experimentally determined to be 2.84 g, which is 0.66 g. more control. Bushiness in the experiment was 4.2 stems per plant versus 3.1 in the control. The weight of the roots of one control plant exceeded that of the experimental plant by 0.07 g (Table 6).

The warm weather in May with sufficient precipitation was favorable for the growth and development of winter wheat. The determination of the development indicators of winter wheat was carried out for the third time on May 28, the plants were in the “lower straw node” phase, all development elements increased significantly. The height of the plants in the control variant was 29 cm, in the 2nd variant using the declared composition - 35 cm.

All other indicators of the development of winter wheat plants using the claimed composition significantly exceed the control ones (Table 7), here the weight of 1 plant exceeds the control by 3.17 g and reaches 7.13 g, the root length is 57 cm (on the control - 51 cm), the weight of the roots of 1 plant is from 1.02 g, in the control it is only 0.57 g). The tillering capacity of winter wheat also exceeds the control value of 3.1 stems per plant and is 4.4.

In the phase of waxy ripeness of winter wheat, in both variants of the experiment, sheaves from 1 ^m2 were taken to determine the structure of the crop (Table 8). Favorable agrometeorological conditions in the first half of summer contributed to the appearance of undergrowth (from 40 to 50 pieces per square meter). The grown pod had matured towards the end of the growing season, so the density was too high. Heavy rains and strong winds during the ripening period caused partial lodging of crops.

Analysis of the crop structure showed that the height in the variant with the application of the declared composition exceeded the height in the control by 6 cm and was close to the long-term average - 108 cm.

The length of the spike in the experiment was 9 cm, which is 1 cm longer than the control.

The total mass of the sheaf in the control area was 1501 g; in the experiment it was 31 g lower.

The number of productive stems in the experiment is 60 pcs. higher than the control (578 stems per square meter).

The productivity of the ear in the control is only 0.68 g, in the experiment this figure is 1.05 g.

The number of grains in an ear in the experiment was 28 pieces, which is slightly less than the average long-term quantity (31), but in the control there were only 18 pieces. per ear

The grain contained 10-20 puny pieces per 1000 grains due to adjustment, so the weight of 1000 grains in both experimental variants was lower than the long-term average (45.3 g), in the control variant 1000 grains weighed 38.8 g, in the experiment - 38.

Biological yield at 14% grain moisture in the control plot was 3.96 t/ha; on plots treated with the drug with the stated composition - 6.7 t/ha.

The main indicator in the experiment is the amount of grain harvested by the combine (Table 9). The grain yield in the control plot is 3.89 t/ha.

The use of the drug with the proposed composition increased the grain yield to 5.31 t/ha, which in agrometeorological conditions of agriculture. year against the background of mineral fertilizer N60P60K60 gave an increase in the yield of winter wheat of the Moskovskaya 40 variety by 36% of the control.

Analysis of grain for protein and gluten content in the grain showed that under the current agroclimatic conditions, treatment of seeds and plants with the provided preparation significantly stimulated the development of plants, but under conditions of heavy rainfall during the period of milky-wax ripeness, lodging was observed, which contributed to the “draining of grain” in the experimental plots , and contributed to a decrease in protein content by 1.6% and gluten by 0.7% compared to the control (protein 13.6%, gluten 26.2%).

The nature of the grain in both variants of the experiment is the same, characteristic of the Moskovskaya variety 40 - 795 g, grain purity 99.6-99.9%.

Snow depth 3-5 cm, soil freezing 3 cm

Plants after thawing are green, viable - most of the leaves are preserved (90%)

All options are treated with insecticides, herbicides, and fungicides.

The area of 1 plot is 80 ^m2 . The experiments were repeated 3 times.

Thus, in agrometeorological conditions of agriculture. year, the drug with the declared composition against the background of mineral fertilizer N ₆₀ P ₆₀ K ₆₀ gave an increase in the yield of winter wheat of the Moskovskaya 40 variety by 36% compared to the control.

Analysis of grain for protein and gluten content in grain is presented in table No. 10.

The nature of the grain in all plots of the experiment is the same, characteristic of the Moskovskaya variety 40-795 g/dm ³ , grain purity 99.6 - 99.9%.

The results of determining the main indicators of winter wheat grain quality showed that the use of RRR with microfertilizers in option 2 had a negative impact on these values. They turned out to be lower than the control ones (protein 13.6%, gluten 26.2).

The results of the experiment to study the effect of the drug with the declared composition on the sowing of winter wheat Moskovskaya 40 showed that this plant growth regulator with a corrective nutritional composition increased the elements of plant mass in the first half of the wheat growing season.

Heavy rains caused the lodging of winter wheat. Due to the lodging of more powerful plant mass during the period of milky-waxy ripeness, in option 2, “draining” of grain was observed. Soil moisture, due to heavy rainfall and lower ventilation, was higher. The grain consumed more carbohydrates and nitrogenous substances for respiration, so the gluten and protein content was lower than in the control variant.

However, under these conditions, the claimed composition increased the yield compared to the control by 36%.

Thus, in production applications to increase the gross and quality indicators of grain, seed treatment and foliar treatment of winter wheat during the tillering phase seems promising.

It should be noted that the recorded indicators of yield and quality of the technology under study under more favorable growing and harvesting conditions (with a guide to long-term average values) could, as expected, show better results.

Example 2.

The object of research is Potatoes of the Ilyinsky variety - mid-early, for table use. Productivity 35-40 t/ha. The variety is relatively resistant to common scab and viral diseases. Moderately susceptible to late blight on tops and tubers, Alternaria blight, and Rhizoctonia blight. Heat and drought resistant.

The research was carried out in a small-plot field experiment according to the scheme presented in Table 1.

The effectiveness of the use of drugs was assessed using the following indicators:

- germination of tubers;

- biometric indicators of plant growth and development;

- weight of the crop and its marketability;

The studies used:

growth regulator: the claimed composition with the following content of components:

orthocresoxyacetic acid triethanolammonium salt 110 g/kg magnesium nitrate 225 g/kg potassium nitrate 220 g/kg monopotassium phosphate 156 g/kg manganese chelate 27 g/kg zinc chelate 81 g/kg copper chelate 67 g/kg iron chelate 90 g/kg boric acid 17 g/kg ammonium molybdate 7 g/kg

chemicals: Abiga Pik, Maxim, Ridomil Gold MC.

Planting material: tubers selected from one heated and sorted seed lot of potatoes. The weight of the planting tubers is 70-80 grams, the eyes are closed.

The experiment to study the drug was carried out under the conditions of the soil-climatic zone of podzolic and sod-podzolic soils of the taiga-forest region of the Russian Federation, on the experimental field of the All-Russian Scientific Research Institute of Agriculture (VNIIKH) (Kraskovo village, Lyubertsy district, Moscow region).

The studies were carried out on soddy-podzolic sandy loam soil with the following agrochemical characteristics: pH _KCl = 4.9-5.0; Ng=3.6-3.7 mg-equiv./100 g of soil; S=2.5-2.6 mg-equiv./100 g of soil; V=41.0-41.5%; high content of mobile phosphorus - 342-350 mg/kg of soil and lower than average content of exchangeable potassium - 64-68 mg/kg of soil; low humus content - 1.5-1.7% humus.

Predecessor: vetch-oat mixture.

Fertilizer background: organic fertilizers were not applied to potatoes; mineral fertilizers (azophoska with the addition of potassium magnesium) in a dose of N60P60K90 were applied locally for cutting ridges in mid-April using two belts using a KRN-4.2 cultivator with fertilizer sowing devices.

Soil cultivation: autumn fall plowing (first ten days of October) - MTZ-82 with a PLN 3.35 plow to a depth of 18-20 cm without a skimmer.

Spring continuous cultivation with harrowing (second - third ten days of April) -KSP-4 + harrows.

Potatoes were planted using a clonal planter SN-4B-K with a row spacing of 75 cm and a planting density of 400 pcs. per 100 m ² (May 4).

Plant care:

- inter-row treatments: two pre-emergence and two post-emergence with hilling, KRN-4.2 (May - July);

- against weeds - herbicides (1st treatment - Zenkor 600 g/ha + Titus 30 g/ha + Trend 200 ml/ha; 2nd treatment - Titus 20 g/ha + Trend 200 ml/ha), May.

- during the growing season, plants were treated 3 times in a tank mixture against late blight and the Colorado potato beetle (Ridomil gold, Ditan + Aktara, Regent) with the exception of experimental plots, where treatment was carried out according to the experimental scheme.

Pre-harvest mowing of tops: KIR-1.5; August 15.

Harvesting: using a KTN-2B potato digger with manual selection of tubers on August 22.

The experiment was carried out in accordance with standard methods set out in the following publications: “Methods of research on potato culture” /M., 1967/; “Guidelines for state testing of fungicides, antibiotics and seed protectants for agricultural crops” /M., 1965/; “Research methodology for protecting potatoes from diseases, pests, weeds and immunity” /M., 1995/; “Methods of physiological and biochemical studies of potatoes” /M., 1999/; “Guidelines for conducting registration tests of agrochemicals and plant growth regulators” /M., 2005/; GOST R53136-2008 “Seed potatoes. Technical conditions".

Statistical processing of the obtained results was carried out using the method of analysis of variance according to B.A. Dospehov “Methodology of field experience (with the basics of statistical processing of research results)” /M., 1985/.

The area of experimental plots in the field experiment was 25 ^m2 (100 potato tubers), repeated three times.

Placement is randomized.

Spraying of planting tubers and vegetative plants on experimental plots was carried out using KWAZAR backpack equipment with a working fluid consumption rate of 10 liters per ton and 300 liters per 1 ha.

The necessary observations and records were carried out on 50 permanent census potato plants at each replication.

Surveys of germination on the Ilyinsky variety (Table 12) showed that treatment of tubers with the drug with the declared composition contributed to the active and friendly germination of potato plants of the Ilyinsky variety in the initial period of the growing season compared to the control variant. Pre-planting treatment of tubers with the drug Maxim did not affect the germination of plants, which was at the control level.

Biometric growth indicators

The results of recording biometric indicators are presented in Table 13. During research on the Ilyinsky variety, no significant effect of the growth regulator with the declared composition on the number of stems was revealed. The table data shows that the drug had an effect on the height of the stems, the weight of the tops and the number of developing tubers. Compared to the control, the indicators increased by 10.1%; 5.8% and 8.9% respectively.

The influence of the claimed composition on potato yield.

Accounts of the total yield and the yield of the marketable fraction (tubers larger than 30 mm) showed that the use of the drug with the declared composition contributed to a significant increase in the gross yield compared to the control (Table 14) and amounted to 5.1 t/ha or 30.3%.

Analyzing the fractional composition of the tubers of the new harvest, it was revealed that the use of the drug with the declared composition contributed to an increase in the yield of the seed fraction of the tubers. In the same variant, a decrease in the number of tubers of the small fraction (<30 mm) was noted. In the reference variant, a decrease in the number of tubers of the large fraction and an increase in the number of tubers of the small fraction were noted.

Thus, the use of a plant growth regulator drug with the declared composition on the Ilyinsky variety did not have a negative impact on the biometric parameters of potato plants. As a result of its use, an increase in stem height was noted compared to the control by 10.1%. In addition, a tendency was revealed for the positive effect of the drug on the weight of tops and the number of developing tubers. Compared to the control, the indicators increased by 5.8% and 8.9%, respectively. In addition, the use of the drug with the declared composition contributed to an increase in gross yield compared to the control and amounted to 5.1 t/ha. The yield of marketable tubers as a result of its use exceeded the control variant by 6.2 t/ha; in the standard by only 2.1 t/ha. On the Ilyinsky variety, in variants using the drug with the declared composition, a tendency was noted to reduce the number of tubers affected by dry rot.

Example 3.

The object of research is potatoes of the “Gala” variety. This table variety is of German selection. The ripening period for a full-fledged harvest is 70-80 days from the moment of planting in the ground. The originator of the variety is NORIKA GMBH (Germany).

The purpose of the work is to study the effect of a plant growth regulator with the declared composition on potato yields.

The preparative form of the claimed composition is a crystalline powder, its composition: Ntot.. - 5.3%; Р2О5-7.8; K2O-14.5; MgO-4.0; Fe-1.1; Mn-0.48; Zn-1.0; Cu-0.9; B-0.3; Mo-0.05% and a synthetic analogue of phytohormone growth - auxin with the following content of components:

orthocresoxyacetic acid triethanolammonium salt 95 g/kg magnesium nitrate 264 g/kg potassium nitrate 200 g/kg monopotassium phosphate 135 g/kg manganese chelate 30 g/kg zinc chelate 67 g/kg copper chelate 80 g/kg iron chelate 110 g/kg boric acid 14 g/kg ammonium molybdate 5 g/kg

Field research was carried out in the spring, in production conditions, on the field of the peasant farm "Bogomaz O.A." in the Bryansk region, Pogarsky district, village. Gri-nevo. The climate of the area is temperate continental with sufficient moisture, moderately cold winters and relatively warm summers. The average annual air temperature is +6°, the duration of the growing season is from mid-April to the third ten days of October, the average long-term precipitation is 590 mm, the average relative humidity is 70%.

Field 47 hectares, soil type - gray forest, with a humus content of 2.5...3%. The predecessor in the field is winter wheat. Fertilizers applied:

- azofoska - 5 c/ha;

- saltpeter - 3 c/ha.

Before planting, the field was plowed and cultivated with a Lemken Karat unit.

Potatoes were planted with a Grimme potato planter over two days in mid-April. When planting, the tubers were treated:

- control - “Prestige” 1 l/t, “Albit” 0.5 l/t

- experiment 1 - “Prestige” 1 l/t, drug with the declared composition 15 g/t

During the period of potato growth, the following PPP treatments were carried out:

1) “Zenkor” 1 l/ha

2) “Infinito” 1.6 l/ha, “Titus” 25 g/ha, “Fusilade Forte” 1 l/ha

3) “Acrobat” 2 kg/ha

4) “Infinito” 1.6 l/ha

5) “Consento” 2 l/ha

6) “Acrobat” 2 kg/ha

7) “Orvego” 1 l/ha

8) "Reglo" 1 l/ha

After the second herbicide treatment, the tested preparations were applied, together with the fungicide “Acrobat”, at the beginning of budding phase (Table 15).

The first digs of tubers; 31-32 days after planting; no shoots. On tubers treated with the drug with the stated composition, a more powerful root system is observed, the number of sprouted sprouts is greater than on the control ones

Digging of plants 44-45 days after planting. Vegetative growth phase. On the treated plants, the vegetative mass is better developed: plants from the control plot do not exceed 20 cm in height, while those treated with the drug reach 20-25 cm. The root system on the treated tubers is more developed than on the control plot, the number of stolon and near-stolon roots is greater.

Digging of plants 74-75 days after planting. The phase of vegetative growth, maximum growth of tubers. Plants for comparison were selected at random. We dug up 5 bushes planted in a row from one furrow. On control it turned out to be 5 kg; on the drug with the declared composition 5.5 kg. It should be noted that in the area with the drug with the declared composition there are more tubers, they are cleaner (no scab damage*) and more even.

Digging of plants 97-98 days after planting. The phase of the tops dying off. Plants were dug up in groups of 5 bushes planted in a row from one furrow. On control it turned out to be 4.7 kg; on the drug with the declared composition 5.5 kg. It should be noted that the development dynamics are expected: the control group has the fewest tubers; in the area treated with the drug with the declared composition, the weight of the tubers is greater due to their number, they are also more even and unaffected by scab than in the control

Table -16 shows the indicators for pre-weighing potato tubers before harvesting. Plants were randomly selected, twice on August 1 (sample -1) and August 23 (sample - 2).

Thus, the data in Table 16 indicate that the biological yield in the experimental plot is at least 20% higher than in the control plot.

This field was harvested during daylight hours on September 11-12. Quantitative yield indicators are given in table - 17.

Summing up the results of this study, we were convinced that the introduction of drugs with the declared composition into the company’s standard technology effectively affects the gross yield of potatoes. It should be noted that with a fairly intensive potato cultivation technology, the application of the drug with the declared composition significantly increased the overall yield by 44 quintals per hectare. Consequently, the introduction of drugs into standard technology allows increasing productivity by more than 10%. It is necessary to note the commercial qualities of the products. In experiment 1, there was an almost complete absence of potato scab disease, whereas in the control plot this disease was much more common. Also, potatoes treated with the drug with the declared composition were distinguished by a more leveled, marketable fraction. The introduction of a biogenic analogue of auxin (orthocresoxyacetic acid triethanolammonium salt) in combination with macro and microelements into important phases of potato growth increased immune properties, improved nutrition processes, promoting healthy and intensive development of the crop. Thus, the tested drug not only increases the gross yield, but also affects the quality and appearance of potatoes.

Claims (2)

A composition for increasing the growth, development of plants and the quality of agricultural crop products, which is a crystalline powder containing orthocresoxyacetic acid triethanolammonium salt, magnesium nitrate, potassium nitrate, monopotassium phosphate, boric acid, ammonium molybdate, as well as chelates of manganese, zinc, copper and iron, with the following content of components per 1 kg of composition, g/kg: orthocresoxyacetic acid triethanolammonium salt 90÷110 magnesium nitrate 225÷275 potassium nitrate 180÷220 monopotassium phosphate 135÷156 manganese chelate 27÷33 zinc chelate 67÷83 copper chelate 67÷83 iron chelate 90÷110 boric acid 13÷17 ammonium molybdate 3÷7