EA044024B1 - LIQUID COMPLEX FERTILIZER - Google Patents

Description

The invention relates to agriculture, namely to liquid complex fertilizers containing colloidal silver, which help increase productivity and are also intended for use together with acaricides and insecticides.

Prior Art

The use of silver in the form of an aqueous solution of silver ions is known from the prior art (https://www.urozhayxxi.com/juss-argentum-agro). The mechanism of action of the drug is that silver ions are fixed and retained on the cell walls of phytopathogenic microorganisms, penetrate their cell wall, and suppress their reproduction. The disadvantage of this approach is that silver in the form of ions is very actively and quickly absorbed by dust and other microparticles, and is also exposed to insolation in the sun. This results in the protective effect being short-lived. Moreover, silver ions, without a substance or form to deliver them, have difficulty penetrating plant tissue. This also limits the use of the drug as a plant growth regulator, as well as when used in conjunction with fungicides.

A composition is known from the prior art, including a chelate form of Ag ⁺ and Cu ²⁺ ions and containing fulvic acid C ₁₃₅ H ₁₈₂ O ₉₅ N ₅ S ₂ as a chelating agent, and it additionally includes 25% of a concentrate of organic matter containing fulvic and amino acids , organic, humic and folic acids, as well as easily accessible to plants: nitrogen at a concentration of 1.25 g/l, phosphorus at a concentration of 5.5 g/l, potassium at a concentration of 10 g/l, calcium at a concentration of 0.3 g/l l, silicon at a concentration of 4 mg/l, iron at a concentration of 0.5 g/l, magnesium at a concentration of 55 mg/l, molybdenum at a concentration of 0.01 mg/l, manganese at a concentration of 0.02 mg/l, zinc in concentration 9 mg/l, boron at a concentration of 1 mg/l, sodium at a concentration of 2.3 g/l, sulfur at a concentration of 0.1 g/l, selenium at a concentration of 0.02 g/l, as well as gibbirelins, auxins, indolyl-3-butyric acid, and cytokinins (RU 2738483, IPC C05F 11/00, A01N 59/00, A01P 3/00, A01P 21/00, published 12/14/2020).

The composition is active as a pesticide with a fairly long-lasting effect, and is also an effective drug for stimulating plant growth.

The closest to the claimed invention is a liquid complex fertilizer containing colloidal silver and a complex of macro- and microelements in salt form, as well as in the form of metal-ethylenediaminetetraacetic acid chelates, and the content of active substances is, g/l: silver - 0.5, boron - 2, copper - 9, zinc - 4.5, manganese - 9, molybdenum - 3, cobalt - 0.3, magnesium - 2, iron 2, potassium - 4 (https://tdahp.ru/pestitsidy/zeromix- alpfa/).

The fertilizer has a complex effect aimed at increasing productivity, and also enhances the effect of chemical fungicides when used together with fertilizer.

The disadvantages of the compositions and fertilizers described above are the relatively low biocidal activity against the common spider mite, the common potato aphid, the tomato yellow leaf curl virus, as well as the insufficient stability of the compositions.

The essence of the invention

The objective of the invention is to create a fertilizer that has a complex, prolonged effect aimed at increasing productivity, as well as insecticidal and antiviral activity.

The technical result is an increase in acaricidal activity against the common spider mite, an increase in insecticidal activity against the common potato aphid, an increase in antiviral activity against the tomato yellow leaf curl virus, an increase in the stability of the fertilizer as a colloidal system, as well as a decrease in the rate of input of acaricides and insecticides when combined with fertilizer.

The technical result is achieved by the fact that the liquid complex fertilizer contains colloidal silver and a complex of macro- and microelements in salt form, as well as in the form of metal ethylenediaminetetraacetic acid chelates, sodium tallow amphopolycarboxyglycinate, polyvinylpyrrolidone and prepared water, which is first desalted using reverse osmosis, then settled in shungite. filter with a particle size of 0.5 to 2 cm and then fed into a dispersant with shungite particles no larger than 0.01 mm in size, with the following component content, g/l:

silver nitrate - 0.9-6;

sodium borohydride - 0.4-2.8 sodium tallow amphopolycarboxyglycinate - 7-46;

polyvinylpyrrolidone - 5-80;

ammonium molybdate - 1.8-7;

sodium octaborate tetrahydrate - 11-40;

copper chelate - 33-70;

zinc chelate - 23-70;

manganese chelate - 27-82;

cobalt chelate - 7-35;

prepared water - 561.2-883.9.

Liquid complex fertilizer is an aqueous colloidal solution that acts

- 1 044024 the substance of which are nano-sized silver particles stabilized by polymers, ensuring their optimal interaction with the leaf surface contains macro- and microelements in salt and chelate forms. The fertilizer is an effective means for correcting leaf nutrition of plants, treating seeds and seeding material for potatoes, vegetables, fruits, rapeseed, etc. The use of modified nano-sized silver particles significantly increases the area of their contact with the plant cuticle, enhances the transport of nutrients and their absorption by the plant. This makes it possible to obtain high biological efficiency in low concentrations, which makes the use of fertilizer cost-effective with minimal risks to the environment.

Information confirming the possibility of implementing the invention

The production of complex liquid fertilizer consists of several stages.

At the first stage, water is prepared, which includes three stages. At the first stage, process water is prepared by reverse osmosis to the demineralized water standard. Then water treatment of desalted water is carried out by settling in a shungite filter for 24 hours, while the size of shungite particles in the filter is from 0.5 to 2 cm. At the final stage, water obtained at the second stage and shungite particles of size are simultaneously fed into the dispersant no more than 0.01 mm.

Shungite is a natural composite, the structure of which is an amorphous microporous quartz frame filled with highly dispersed (about 1 micron) particles of aluminosilicate minerals. The water obtained at the first stage affects harmful microflora, plant spores, algae, viruses, biological toxins, as well as helminth eggs. In addition, the water is additionally mineralized due to the macro- and microelements included in shungite.

At the second stage, silver is synthesized in nanosized form. The mixing reactor is filled with water prepared at the first stage, in which silver nitrate is dissolved. Then, water prepared at the first stage is poured into a separate container No. 1 with a volume of 1.5 m ³ and sodium tallow amphopolycarboxyglycinate (Amfolac 7-TX) is added with stirring. After mixing, the Amfolac 7-TX solution is pumped into a mixing reactor using a pump. The temperature in the reactor should be in the range of 15 -25°C and constantly monitored. In container No. 2 with a volume of 1.5 m ³ , water prepared at the first stage is also poured and a portion of sodium borohydride is sprinkled. After complete dissolution of sodium borohydride, the mixture is fed into a mixing reactor. At the end of the synthesis process in a mixing reactor, a homogeneous transparent light brown liquid is obtained.

In the synthesis reaction of silver in nanosized form, sodium borohydride serves as a reducing agent for silver nitrate. Amfolac 7-TX is an amphoteric surfactant that allows you to stabilize a highly dispersed colloidal system including nano-sized silver particles. The resulting system has high aggregative stability in a wide pH range (4-12), is capable of redispersing after drying, tolerates repeated freezing/thawing, and is insensitive to the effects of anions and singly charged cations.

At the third stage, the colloidal system obtained in the second stage is saturated with nutrients, which are macro- and microelements in salt and chelate forms. Before adding batteries, polyvinylpyrrolidone is added to the mixing reactor and stirred until completely dissolved. Ammonium molybdate, sodium octaborate tetrahydrate, copper chelate, zinc chelate, manganese chelate and cobalt chelate are then added to the reactor alternately. The mixing time for all components is at least one hour.

Polyvinylpyrrolidone acts as an additional stabilizing agent of the colloidal system, preventing the formation of large agglomerates of dispersed particles and their precipitation. As a result, the introduction of this compound into the solution makes it possible to prolong the biocidal effect of the fertilizer.

The use of copper, zinc, manganese and cobalt chelates in fertilizers is preferable due to the high absorption of chelate complexes by plants compared to free metal ions.

At the final stage of fertilizer production, finished products are bottled. After all batteries are completely dissolved in the mixing reactor, a sample is taken for analysis in the laboratory. Next, if the quality of the product meets all requirements, the fertilizer is pumped into a filling container. The finished product is filled on automated lines into plastic canisters.

Using the above method, the following fertilizer compositions were obtained (see Table 1)

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Table 1

Fertilizer compositions

Component Component content, g/l Composition 1 Composition 2 Composition 3 Composition 4 Composition 5 Silver nitrate 0.9 2 4.5 5 6 Sodium borohydride 0.4 1 1.6 2.3 2.8 Sodium T allic amphopolycarboxyglycinate 7 10 25 33 46 Polyvinylpyrrolidone 5 17 38 67 80 Ammonium molybdate 1.8 3 5.3 6.1 7 Sodium octaborate tetrahydrate eleven 15 27 35 40 Copper chelate 33 45 53 64 70 Zinc chelate 23 34 43 59 70 Manganese chelate 27 36 48 72 82 Cobalt chelate 7 18 26 thirty 35 Prepared water 883.9 819 728.6 626.6 561.2 Total: 1000 1000 1000 1000 1000

To confirm the acaricidal effectiveness of the fertilizer against the common spider mite, as well as the insecticidal effectiveness against the common potato aphid, laboratory studies were carried out.

The studies were carried out according to standard methods for assessing the toxicity of pesticides for arthropods using different methods of treating experimental arthropods in order to select the optimal method of applying it to the test object, in which the biological activity of the fertilizer will be maximally manifested: dipping the leaves of the forage plant into fertilizer solutions of different concentrations, followed by replanting them test objects or dipping parts of the food plant colonized by the test objects into them.

All experimental variants were performed in 3-4 repetitions. After treatment, the arthropods were kept under thermostated conditions in cages. The duration of observations of surviving individuals depended on the test object and stopped after the onset of high mortality in the control or the appearance of individuals of the next generation. In all variants of the experiment, a control was necessarily provided - a variant with water treatment.

An indicator of the biological activity of the fertilizer was a decrease in the number of experimental individuals relative to the initial one, adjusted for control according to the standard Henderson-Tilton formula:

BA (%) = 100-(1-Op-Kd/Od-Kp), where

BA - biological activity, expressed as a percentage reduction in abundance, adjusted for control; Od is the number of living individuals in the experiment before treatment, Op is the number of living individuals in the experiment after treatment; Kd is the number of living individuals in the control before treatment, Kp is the number of living individuals in the control after treatment.

To assess the ovicidal effect of the fertilizer on the eggs of the common spider mite, bean leaves were colonized with 5 fertilized females, which were removed after a day. Leaves with one-day eggs were treated by immersing them in aqueous solutions of fertilizer of different concentrations. Observations carried out over 11 days revealed that the development of experimental eggs of the autumn generation was slowed down, almost 2 times, in comparison with the summer ones. Against this background, during the accounting period, almost complete (94.9-100%) hatching of larvae from eggs occurred in all variants of the experiment, regardless of the concentration tested (see Table 2). Thus, it was established that the fertilizer does not have an ovicidal effect on the eggs of the common spider mite.

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table 2

Toxicity of fertilizer for eggs of common spider mite (laboratory experiment)

Experience Option Repetition Number of eggs per sheet % eggs hatched from larvae before processing eggs after processing by day of registration 8 eleven 8 eleven Dipping 1 7 3 7 42.9 100 populated 2 9 3 9 33.3 100 leaf eggs 3 12 3 12 25.0 100 in 0.01% aqueous 4 10 4 10 40.0 100 fertilizer solution Wed 9.5 3.3 9.5 35.3 100 Dipping 1 22 4 21 18.2 95.5 inhabited 2 13 4 13 30.8 100 leaf eggs 3 17 5 16 29.4 94.1 in 0.1% aqueous 4 20 4 18 20.0 90.0 fertilizer solution SR 18.0 4.3 17.0 24.6 94.9 Dipping 1 25 • 5 22 20.0 88.0 inhabited 2 24 8 24 33.3 100 leaf eggs 3 20 7 20 35.0 95.0 in 1.0% aqueous 4 19 6 19 31.6 100 fertilizer solution Wed- 22.0 6.5 21.0 30.0 95.8 Control 1 17 3 17 17.6 100 2 14 3 14 28.6 100 3 10 4 10 thirty 100 4 AND 4 eleven 36.4 100 Wed 13.0 3.5 13.0 28.2 100

An assessment of the effect of the fertilizer on the imago of the common mite using different treatment methods revealed the presence of contact toxic properties of the fertilizer in relation to this phase of pest development. At the same time, it was found that the toxic properties of the fertilizer are most fully manifested when the mite is directly treated (dipping leaves infested with imagoes in fertilizer solutions) than when planted on the surface of a food plant treated with fertilizer (see Table 3). However, the toxicity values with the optimal method of applying the fertilizer at 1% concentration did not exceed 50%.

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Table 3

Toxicity of fertilizer to adult spider mites under different treatment methods (laboratory experiments)

Experience Option Repetition Number of adults per leaf by day of survey Decrease in tick numbers relative to the initial one, adjusted for control, %, after treatment by day of counting BEFORE processing After processing 3 5 7 3 5 7 Planting imago on a solution-treated leaf Dipping the sheet in 1 17 16 40 116 5.9 20.3 24.0 0.75% aqueous 2 10 8 34 105 20.0 0 0 fertilizer solution 3' 9 9 16 101 0 2.2 0 Wed- 11.0 11.0 33.3 107.3 8.6 7.7 8.0 Dipping the sheet in 1 19 13 31 93 31.6 44.8 45.5 1.0% aqueous solution 2 15 12 24 86 20.0 45.8 36.2 fertilizers 3 9 9 25 81 0 5.9 0 sr· 14.3 11.3 26.7 86.7 17.2 32.2 27.2 Control 1 15 15 45 126 - - - 2 13 13 38 138 - - - 3 17 17 50 140 - - - SR 15.0 15.0 44.3 137.8 - - - Treatment of a leaf colonized by adults Dipping 1 10 6 32 61 40.0 12.3 25.6 inhabited imago 2 10 7 39 48 30.0 0 41.5 sheet 3 10 6 40 56 30.0 0 31.7 in 0.75% aqueous 4 10 6 28 58 40.0 23.3 29.3 fertilizer solution sr· 10.0 6.3 34.8 55.8 35.0 8.9 32.0 Dipping 1 10 5 25 46 50.0 31.5 43.9 inhabited imago 2 10 6 24 44 40.0 34.2 50.0 sheet 3 10 6 27 44 40.0 26.0 46.3 in 1.0% aqueous 4 10 4 21 36 60.0 42.5 56.1 fertilizer solution SR 10.0 5.3 24.3 41.8 47.5 33.6 49.1 Control 1 10 10 36 88 - - - 2 10 10 37 68 - - - 3 10 10 41 82 - - - 4 10 10 32 90 - - - sr· 10.0 10.0 36.5 82.0 - - -

An increase in fertilizer concentrations in the range from 5 to 20% contributed to a gradual increase in its toxicity.

However, this increase was insignificant and reached on average only 73.4% when treated with a 20% fertilizer concentration (see Table 4).

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Table 4

Toxicity of fertilizer to adults of common spider mites (laboratory experiment)

Experience Option Repetition Number of adults per leaf by day of survey Decrease in tick numbers relative to the initial one, adjusted for control, %, after treatment by day of counting before processing After processing 3 7 10* 3 7 10 Dipping 1 25 12 12 27 52.0 52.0 44.0 inhabited imago 2 22 12 12 28 45.5 45.5 34.0 sheet 3 22 12 12 thirty 45.5 45.5 29.3 at 5.0% aqueous 4 20 10 10 24 50.0 50.0 37.8 fertilizer solution sr· 22.3 11.5 11.5 27.3 48.3 48.3 36.3 Dipping 1 26 9 9 9 65.4 65.4 56.2 inhabited imago 2 thirty 10 10 10 66.7 66.7 67.2 sheet 3 19 9 9 9 57.9 57.9 56.4 at 10.0% aqueous 4 23 8 8 8 60.9 60.9 57.2 fertilizer solution Wed- 24.5 9.0 9.0 9.0 62.7 62.7 593 Dipping 1 20 6 6 12 70.0 70.0 68.9 inhabited imago 2 22 7 6 14 68.2 72.7 67.0 sheet 3 17 6 6 12 64.7 64.7 63.4 at 15.0% aqueous 4 20 7 7 15 65.0 65.0 61.1 fertilizer solution Wed 19.8 6.5 6.3 13.2 66.9 68.1 65.1 Dipping 1 18 4 4 9 77.8 77.8 74.1 inhabited imago 2 19 3 3 8 84.2 84.2 78.2 sheet 3 17 4 3 8 76.5 82.4 75.6 at 20.0% aqueous 4 18 4 4 8 66.7 77.8 65.5 fertilizer solution sr· 18.0 3.8 3.5 8.3 76.3 77.8 73.4 Control 1 eleven eleven eleven 23 - - - 2 18 18 18 33 - - - 3 13 13 13 25 - - - 4 15 15 15 29 - - - sr· 14.3 14.3 14.3 27.5 - - -

The results obtained from assessing the biological activity of the fertilizer for the common spider mite indicate that it has contact toxic properties against this pest. However, increasing the concentration of fertilizer even to 20% did not allow increasing its toxicity to ticks by more than 78.0%. This toxicity indicator is clearly not sufficient for a pest that quickly restores its numbers and develops in more than 10 generations per season, forming large populations on various crops.

The results obtained from assessing the effect of the fertilizer on the common potato aphid using different methods of processing indicate that somewhat greater toxicity, as in the case of the common spider mite, occurs when the insect is directly treated, in comparison with its replanting on the treated surface of the food plant. (see Table 5).

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Table 5

Toxicity of fertilizer for common potato aphids (laboratory experiments)

Experience Option Repetition Number of adults and larvae per leaf by day of survey Reduction in the number of aphids relative to the initial one, adjusted for control, %, per day of survey after treatment BEFORE processing after processing 1 3* eleven 3* Planting an imago on a leaf treated with a solution Dipping the leaf in a 0.01% aqueous solution of fertilizer, followed by replanting with aphids 1 2 3 Wed. 18 56 81 48.3 18 55 78 47.0 18 35 50 31.0 0 1.8 3.7 1.8 0 45.6 46.2 30.6 Dipping the leaf in a 0.1% aqueous solution of fertilizer, followed by replanting with aphids 1 2 3 Wed 54 47 47 49.3 54 47 47 49.3 28 24 25 31.2 0 0 0 0 54.8 55.5 52.3 54.2 Control 1 2 3 sr· 24 33 thirty 29.0 24 33 thirty 29.0 28 36 36 33.3 Treatment of a leaf colonized by adults Dipping a gley-infested leaf into a 0.1% aqueous fertilizer solution 12 3 Wed- 34 21 20 25.0 34 21 20 25.0 29 17 19 21.0 0 0 0 0 50.0 52.5 32.1 44.9 Dipping of populated gley leaves in a 1% aqueous fertilizer solution 1 2 3 Wed 41 37 40 39.3 41 36 39 38.6 thirty 26 24 26.6 0 2.7 2.5 1.7 57.1 58.8 64.8 60.2 Control 1 2 3 Wed- thirty 40 20 30.0 thirty 40 20 30.0 39 44 45 42.6 -

* after 3 days, 100% death of aphids was observed in all experimental variants, including control

It should be noted that, regardless of the method of treating the insect, increasing the concentration of the aqueous fertilizer solution by 10 times did not lead to a significant increase in its biological activity. As a result, the maximum toxic effect from a 1% concentration of fertilizer when treating a leaf colonized by adults was only 60.2%.

Taking into account the results of laboratory studies, we can recommend the combined use of fertilizers with insecticides and acaricides to enhance the biocidal activity of the tank mixture by 30-50%, while reducing the consumption of insecticides and acaricides by 15-20%.

The insecticidal effect of fertilizer is due to the action of a complex of adjuvants, which, when they enter the respiratory system of an insect, disrupt the respiratory processes.

To confirm the antiviral effectiveness of the fertilizer against the tomato yellow leaf curl virus (TYLCV), studies were conducted on the Momotaro variety.

The control option is the standard tomato growing technology adopted on the farm, which involves complete mineral nutrition of plants, as well as protection of tomato plants starting from the germination phase through 12 treatments during the growing season (fungicide, bactericide Vino 95, insecticide Imidoclaprid in recommended dosages).

Option 1 - spraying plants with a 0.5% aqueous solution of fertilizer 6 times during the growing season.

Option 2 - spraying plants with a 1% aqueous solution of fertilizer 6 times during the growing season.

The experiment was carried out in triplicate, and one repetition was considered to be one row in the field with 20 tomato plants in a row. Each variant contained 60 tomato plants (see Table 6).

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Claims (1)

Table 6 Antiviral activity of fertilizer on tomato variety Momotaro Observation dates Control variant (with replicates) Total plants in the row\ affected Option 1 (with repetitions) Total plants in the row\affected Option 2 (with repetitions) Total plants in the row affected 01/14/2019 20\0 20\3 20\4 20\1 20\2 20\2 20\2 20\1 20\1 01/21/2019 20\2 20\4 20\4 20\1 20\3 20\2 20\2 20\2 20\1 01/28/2019 20\4 20\6 20\4 20\2 20\3 20\2 20\2 20\2 20\1 02/04/2019 20\7 20\6 20\5 20\2 20\3 20\2 20\2 20\2 20\1 02/11/2019 20\7 20\6 20\6 20\2 20\3 20\2 20\2 20\2 20\1 02/18/2019 20\7 20\7 20\6 20\2 20\3 20\2 20\2 20\2 20\1 Final accounting 02/28/2019 20\7 20\7 20\6 20\2 20\3 20\2 20\2 20\2 20\1 Average % of Infected Plants in the final count 33.3 11.6 8.3 Based on observations of the growing season of plants, it can be noted that the use of fertilizer (0.5%, 1% aqueous solution) in the form of leaf treatments restrained the development of the viral disease yellow curl of tomato and prevented its spread to neighboring plants, while the concentration has an advantage in effectiveness 1% Zeromix. Thus, we can recommend the use of fertilizer in a concentration of 1% solution on the tomato crop in the form of leaf treatments, starting from the germination phase every 7-10 days, depending on the prevalence of the tomato yellow curl virus, and at least 6 treatments per growing season. Silver nanoparticles stabilized by Ampholac 7-TX and polyvinylpyrrolidone have the ability to interact with DNA and RNA proteins of viruses. The mechanism of action consists of three stages. At the first stage, interaction occurs with the protein shell of the virus to keep it from attaching to plant cells. At the second stage, ions and ROS (reactive oxygen species) are produced, which destroy the protein shell, DNA and RNA of viruses. At the final stage, nanoparticles penetrate into the plant cell, followed by interaction with enzymes to prevent replication and further spread of the virus. In addition, the antiviral effect of the fertilizer is due to the presence in its composition of a complex compound of fullerene with polyvinylpyrrolidone, which inhibits virus reproduction. Thus, the fertilizer contains tall sodium amphopolycarboxyglycinate, polyvinylpyrrolidone, as well as prepared water, which is first desalted using reverse osmosis, then stood on a shungite filter with a particle size of 0.5 to 2 cm and then fed into a dispersant with shungite particles of no more than 0.01 mm, with the content of components in accordance with the compositions given in table. 1 allows the invention to be implemented to achieve the stated technical result. CLAIM Liquid complex fertilizer containing colloidal silver and a complex of macro- and microelements in salt form, as well as in the form of metal-ethylenediaminetetraacetic acid chelates, sodium tallow amphopolycarboxyglycinate, polyvinylpyrrolidone and prepared water, which is first desalted using reverse osmosis, then settled in a shungite filter with particle size from 0.5 to 2 cm and then fed into a dispersant with shungite particles no larger than 0.01 mm in size, with the following component content, g/l: silver nitrate - 0.9-6; sodium borohydride - 0.4-2.8; sodium tallow amphopolycarboxyglycinate - 7-46; polyvinylpyrrolidone - 5-80; ammonium molybdate - 1.8-7; sodium octaborate tetrahydrate - 11-40; copper chelate - 33-70; zinc chelate - 23-70; manganese chelate - 27-82; cobalt chelate - 7-35; prepared water - 561.2-883.9. Eurasian Patent Organization, EAPO Russia, 109012, Moscow, Maly Cherkassky lane, 2