RU2267924C1 - Plant growth promoting method - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: method involves promoting plant growth by utilizing aqueous solutions of saturated dicarboxylic acids, such as malonic acid, oxalic acid, malic acid or succinic acid, with concentration of said acid in aqueous solution constituting 10^-11 - 10^-15 mol/l.

EFFECT: reduced costs for carrying out process, improved ecological safety owing to reduced amount of promoter used, and increased efficiency.

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Description

The invention relates to the field of agriculture, specifically to chemicals that stimulate plant growth, and can be used both in pre-sowing seed treatment and in growing plants in open and closed ground.

Plant growth stimulants are currently gaining in popularity. They contribute to the increase in the yield of various crops, improving the quality of agricultural products. The economic benefits of using synthetic growth stimulants are many times greater than the cost of their acquisition. Many of them have found application in practice. However, their wide distribution is hindered, firstly, by the fact that under the current conditions, with a sharp reduction in the production of many synthetic drugs, including plant growth stimulants, they become scarce, which, in turn, leads to an increase in their cost. Secondly, like any biologically active substances, growth stimulants require very careful handling. With an overdose of these compounds, you can not only not get the expected effect, but also encounter directly opposite results. However, the concentration range of growth stimulants is usually very narrow and specific for different stages of plant development, so the likelihood of an overdose is quite high. But the most important thing is that the mechanism of the effect of stimulants on growth processes in plants is still not fully understood, it is impossible to predict the impact on agricultural organisms (humans or animals) of agricultural products grown using growth stimulants.

Of all the known growth stimulants, only about humic substances, we can definitely say that in the human and animal body they also exhibit a positive physiological effect, which is confirmed by the results of studies by scientists in many countries. As for other groups of growth stimulants, such large-scale studies have not been conducted with them, and it is not known how their use in the cultivation of grain, feed and other agricultural products will affect the development of a living organism.

Therefore, the task of reducing the amount of growth promoter used while maintaining its effectiveness is of particular relevance.

As growth stimulators in agriculture, both individual compounds and compositions containing growth-promoting substances are used.

It is known from the prior art that certain limiting dicarboxylic acids are used as growth promoters in the form of aqueous solutions or as part of water-soluble compositions.

A known composition for increasing the resistance of plants to diseases by treating seeds and vegetative plants based on aqueous solutions of chitosan, in which heteroauxin and succinic and lactic acid or a mixture of glutamic acid in the amount of 0.001-0.005 and 0.004-0 are contained as plant growth regulators, 5 wt.% (10 ^-7 · 5 · 10 ^-7 and 4 · 10 ^-7 -5 · 10 ^-5 mol / l, respectively (US Pat. RF No. 2158510, 7 IPC A 01 N 25/00, 37/04, 37/44, publ. 2000).

Also known is a tool that simultaneously stimulates the growth of plants and increase their resistance to drought (US Pat. RF No. 2133092, 6 IPC A 01 N 37/02, publ. 1999), which includes succinic, maleic, fumaric and formic acids, 2 ( 5H) -furanone and β-formyl acrylic acid. This tool is used in the form of aqueous solutions with a mass fraction of 0.01-0.0001% (10 ^-6 -10 ^-8 mol / l (optimal concentration is 10 ^-7 mol / l). The plants are treated by soaking the seeds and spraying the plants in the budding phase.

A known method of stimulating plant growth (US Pat. RF No. 2088086, 6 IPC A 01 N 59/00, publ. 1997), which consists in treating the seeds and watering the plants during the growing season with an aqueous solution containing 10 ^-6 -10 ^-4 mol / l of hydrogen peroxide, 10 ^-6 -10 ^-5 g / ion of copper ions and 10 ^-6 -2 · 10 ^-6 mol / l of oxalic acid.

As can be seen from the above sources, for the applied growth stimulants, the optimal concentration is 10 ^-5 -10 ^-7 mol / L. With a decrease in concentration below 10 ^-7 mol / L, their stimulating effect sharply decreases.

One of the most common plant growth stimulants is succinic acid (G.N. Chupakhina, A.Yu. Romanovich. A possible mechanism for stimulating growth processes with succinic acid. Theoretical and applied aspects of biology. Kaliningrad, 1999, pp. 46-51). Succinic acid is used in the form of an aqueous solution of the optimal concentration of 10 ^-4 -10 ^-5 mol / L. A further decrease in concentration to 10 ^-6 -10 ^-7 mol / L reduces the growth-promoting ability of succinic acid to the level of control experiments. This method is adopted as a prototype.

The technical problem solved by the invention is to reduce the cost of the method, increasing its efficiency and environmental safety by reducing the amount of stimulator used while increasing its effectiveness.

The technical problem is solved in that in the method of stimulating plant growth, including seed treatment and spraying the plants during the growing season with an aqueous solution of dicarboxylic acid, malonic, oxalic, malic or succinic acid is used as the limiting dicarboxylic acid at a concentration of 10 to ¹¹ - 10 ^-15 mol / L.

The invention consists in the following. As follows from the prior art, aqueous solutions of certain saturated dicarboxylic acids or mixtures thereof with other components were used as plant growth stimulators, but in a limited concentration range from 10 ^-3 to 10 ^-8 mol / l (optimally 10 ^-3 -10 ^-6 ) It is well known that when the concentrations decreased below 10 ^-7 -10 ^-8 mol / L, their biological activity decreased to a control level and lower, therefore, it was naturally believed that such solutions did not have growth-promoting properties. The studies conducted by the authors unexpectedly showed that the biological activity of saturated dicarboxylic acids does not disappear with a decrease in concentration, but is retained, with some acids having another maximum in the concentration range of 10 ^-11 -10 ^-15 mol / L. The biological activity of a number of the most common limiting dicarboxylic acids was studied - citric, maleic, malonic, lactic, fumaric, oxalic, malic and succinic acids, for which solutions with a concentration of (mol / l) were prepared: 10 ^-3 , 10 ^-7 , 10 ^-11 , 10 ^-15 , 10 ^-17 and their effect on radish productivity was studied by pre-sowing treatment (seed soaking) and spraying of vegetative plants.

The proposed solutions of the inventive growth stimulant are prepared according to known methods as follows.

Initially, 1 liter of a 0.1 mol / L solution is prepared, for example, succinic acid in distilled water. Then, an aliquot of 100 ml was taken from this solution and adjusted in a volumetric flask to 1000 ml and so on to obtain a solution of the required concentration. So, to obtain a solution with an acid concentration of 10 ^-17 mol / L, this operation is repeated 8 times.

The experiments showed that in malonic, oxalic, malic and succinic acids, biological activity has two maxima - one in the concentration range of 10 ^-3 -10 ^-6 mol / l and the second maximum in the region of ultra-low concentrations of 10 ^-11 -10 ^-15 mol / l, while the rest of this effect is absent.

The analysis of the prior art did not allow to find any sources of information that would describe methods of stimulating plant growth with aqueous solutions of malonic, oxalic, malic and succinic acids of the claimed concentration, which confirms the compliance of the proposed method with the “novelty” protection criterion.

From the analysis of the prior art it is known to use aqueous solutions of certain saturated dicarboxylic acids as plant growth stimulants, but at a much higher concentration (optimal concentrations of 10 ^-3 -10 ^-6 mol / l). Moreover, in a number of works it was noted (see above) that aqueous solutions of these acids with a concentration below 10 ^-7 do not have stimulating activity.

The effect of increasing growth-promoting activity, such as limiting dicarboxylic acids such as malonic, oxalic, malic and succinic, discovered in the range of ultra-low concentrations of 10 ^-11 -10 ^-15 mol / L, which was first discovered by the authors of the present invention, does not follow clearly from the structure and known properties of these acids. Therefore, the present invention meets the eligibility criterion of "inventive step".

The possibility of implementing the claimed invention is confirmed by the following examples.

EXAMPLE 1. The effect of presowing treatment of seeds with solutions of succinic, malonic, citric, lactic and malic acids on radish productivity.

For experiments used mid-early radish variety "National". Sowing was carried out on May 25 to a depth of 2 cm. The area of the experiment was 1 m ² . The experiments were performed in triplicate. Presowing acid treatment consisted in soaking 200 radish seeds in an acid solution in the range of the claimed concentrations for 30 minutes. Harvested on June 12th. The yield and analysis results of the grown radish are shown in table 1.

Table 1
The effect of presowing seed treatment with solutions of malonic, succinic, citric, lactic and malic acids on radish productivity. The concentration of acid, mol / l Mass fraction of dry matter The average mass of the root crop Productivity Absolute value,% % to control The absolute value, g % to control Absolute value, t / ha % to control Malonic acid 10 ^-3 5.74 98 6.29 48 151 179 10 ^-7 5.08 86 8.94 69 288 270 ^10-11 5.92 101 9.26 71 338 400 10 ^-15 4.62 79 8.02 62 249 294 10 ^-17 5.86 99 5,0 40 84.7 102 succinic acid 10 ^-3 5.73 98 5.78 44 186 113 10 ^-7 6.33 108 6.41 49 271 175 ^10-11 5.02 85 6.56 fifty 281 202 10 ^-15 6.22 106 8.19 63 340 354 10 ^-17 5.86 99 5.1 45 84.5 one hundred Lemon acid 10 ^-3 6.53 112 9.10 70 23.7 28 10 ^-7 6.05 103 8.15 63 27.7 32 ^10-11 6.37 109 9.20 71 33.1 39 10 ^-15 6.18 105 11.70 90 30,4 35 10 ^-17 5.85 99 12.8 98 83.8 96 Lactic acid 10 ^-3 7.17 122 9.05 70 35.3 41 10 ^-7 6.60 112 13,20 101 52.6 61 ^10-11 6.82 116 5.10 39 25.0 29th 10 ^-15 6.72 114 6.60 51 29.0 34 10 ^-17 5.87 one hundred 4.9 33 84.0 97 Apple acid 10 ^-3 7.27 124 12.10 93 42.3 59 10 ^-7 6.68 114 9.95 77 43.7 51 ^10-11 5.40 92 16.40 31 91.6 107 10 ^-15 4.98 85 16.90 130 91.0 106 10 ^-17 5.86 99 12.9 99 85.0 98 The control 5.87 13.0 84.5

EXAMPLE 2. The effect of presowing and foliar treatment with solutions of succinic, malonic, citric, lactic and malic acids on radish productivity.

For experiments used mid-early radish variety "National". Sowing was carried out to a depth of 2 cm. The distance between the plants in the row was 2.5 cm, and between the rows - 10 cm. The experimental area was 1 m ² . The experiments were performed in triplicate. Presowing acid treatment consisted in soaking 200 radish seeds in an acid solution in the range of the claimed concentrations for 30 minutes. The first treatment of vegetative radish plants was carried out in the phase of the appearance of the first pair of true leaves - June 3, and the second - June 10. It consisted in spraying a test plot with a size of 1 m ² 0.1 l of an acid solution corresponding to example 1 concentration.

Harvested on June 12th. The yield and analysis results of the grown radishes are shown in table 2.

table 2
The effect of presowing and foliar treatment with solutions of malonic, succinic, citric, lactic and malic acids on radish productivity. The concentration of acid, mol / l Mass fraction of dry matter The average mass of root crops Productivity Absolute value,% % to control The absolute value, g % to control Absolute value, t / ha % to control Malonic acid 10 ^-3 6.21 105 7.47 57 280 332 10 ^-7 5.34 91 8.35 64 292 346 ^10-11 5.29 90 9.33 72 382 453 10 ^-15 5.99 103 7.71 59 297 351 10 ^-17 5.86 one hundred 7.0 54 84.5 one hundred succinic acid 10 ^-3 5.93 101 6.88 53 186 220 10 ^-7 5.69 97 8.75 67 271 321 ^10-11 5.39 92 10.05 77 281 333 10 ^-15 4,50 76 9.85 76 340 402 10 ^-17 4.85 83 7.71 59 84.3 98 Lemon acid 10 ^-3 7.16 122 6.35 49 20.9 24 10 ^-7 6.15 105 11.20 86 31.3 37 ^10-11 6.83 116 9.90 76 36.6 43 10 ^-15 6.18 105 8.10 62 34.0 40 10 ^-17 5.81 97 4.98 46 84.0 99 Lactic acid 10 ^-3 6.71 114 13.40 103 68,2 79 10 ^-7 6.33 108 13.50 104 63.7 74 ^10-11 6.99 119 11.30 87 39.7 46 10 ^-15 6.21 106 12.30 95 62.8 73 10 ^-17 5.85 99 12,99 99 84.5 one hundred Apple acid 10 ^-3 6.73 115 16.40 126 113 131 10 ^-7 6.38 109 10.80 83 69.9 81 ^10-11 6.67 113 14.90 115 89.7 105 10 ^-15 5.78 98 14.10 108 116 135 10 ^-17 5.87 one hundred 13.1 101 86.0 102 The control 5.87 13.0 84.5

EXAMPLE 3. The effect of presowing treatment of seeds with solutions of oxalic, maleic and fumaric acids on radish productivity. The experiment was carried out under the conditions of example 1, but oxalic, maleic and fumaric acids in the declared concentrations were used as acids. The yield and analysis results of the grown radishes are shown in table 3.

Table 3
The effect of presowing treatment with solutions of maleic, fumaric and oxalic acids on radish productivity. The concentration of acid, mol / l Mass fraction of dry matter The average mass of root crops Productivity Absolute value,% % to control The absolute value, g % to control Absolute value, t / ha % to control Maleic acid 10 ^-3 4.98 126 13.7 92 74.0 78 10 ^-7 3.43 87 6.49 44 24.0 25 ^10-11 5.18 131 13.52 91 87.5 92 10 ^-15 4.26 108 19.50 131 97.5 103 10 ^-17 3.96 one hundred 14.83 one hundred 94.5 99 Fumaric acid 10 ^-3 4.81 122 15.89 107 71.5 75 10 ^-7 5.77 146 6.67 45 18.0 19 ^10-11 5.28 134 12.81 86 80.7 85 10 ^-15 4.76 121 14.82 99 83.0 87 10 ^-17 3.94 one hundred 14.81 98 93.0 97 Oxalic acid 10 ^-3 5.48 139 17.90 121 68.0 72 10 ^-7 4.15 105 15.62 105 100.0 105 ^10-11 4.66 118 7.52 51 20.3 21 10 ^-15 4.68 119 21.30 143 115.0 121 10 ^-17 3.97 101 14.82 99 93.5 98 The control 3.95 14.85 95.0

EXAMPLE 4. The effect of presowing and foliar treatment with solutions of oxalic, maleic and fumaric acids on radish productivity.

The experiment was carried out under the conditions of example 2, but oxalic, maleic and fumaric acids in the concentrations corresponding to example 3 were used as acids. The yield and analysis results of the grown radishes are shown in table 4.

Table 4
The effect of presowing and foliar treatment with solutions of maleic, fumaric and oxalic acids on radish productivity. The concentration of acid, mol / l Mass fraction of dry matter The average mass of root crops Productivity Absolute value,% % to control The absolute value, g % to control Absolute value, t / ha % to control Maleic acid 10 ^-3 5.38 136 18.12 122 87.0 92 10 ^-7 5.10 129 9.70 65 32,0 34 ^10-11 4.97 126 14.20 95 98.0 103 10 ^-15 4.93 125 14.22 96 69.7 73 10 ^-17 3.91 98 14.80 98 92.5 97 Fumaric acid 10 ^-3 5.20 132 24.10 162 94.0 99 10 ^-7 5.11 129 6.58 44 25.0 26 ^10-11 5.05 128 14.72 99 78.0 82 10 ^-15 4.46 113 19.74 133 75.0 79 10 ^-17 3.94 99 14.84 99 95.0 one hundred Oxalic acid 10 ^-3 5.03 127 25.80 174 113.5 119 10 ^-7 4.34 110 25.12 169 160.8 169 ^10-11 4,59 116 9.19 62 34.0 36 10 ^-15 5.16 131 22.36 151 123.0 129 10 ^-17 3.95 one hundred 14.75 98 96.0 102 The control 3.95 14.85 95.0

An analysis of tables 3 and 4 shows that an increase in biological activity is observed only in oxalic acid.

Thus, the proposed method allows, firstly, to significantly reduce the amount of stimulant used, which virtually eliminates the likelihood of an overdose, reduces the cost of the method and increases its environmental safety, and secondly, allows to increase the effectiveness of stimulation due to previously unknown increase effect growth-promoting activity of malonic, oxalic, malic and succinic acid in the claimed concentration range.

Claims (1)

A method of stimulating plant growth, including seed treatment and spraying of plants during the growing season with an aqueous solution of saturated dicarboxylic acid, characterized in that malonic, oxalic, malic or succinic acid is used as the ultimate dicarboxylic acid when its concentration in the aqueous solution is 10 ^-11 -10 ^{- 15} mol / l.