RU2017424C1 - Method for regulating growth of plants - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: plants are treated by complex compound of ferrum and 1-hydroxyethylidenephosphonic acid. Solution having 0.4·10^-4 - 1.0·10^-4 ml M concentration is used for hydroponics, for ground conditions dose 15-75 kg per 1 hectare being used. EFFECT: improves efficiency of the method.

Description

 The invention relates to agriculture, namely to plant growing on carbonate, calcareous soils and in hydroponic conditions, and can be used to regulate plant growth.

 It is known that disturbances in plant nutrition of iron are the main cause of chlorosis in crops on carbonate and calcareous soils [1]. Due to the neutral and slightly alkaline reaction of nutrient substrates, the translocation of iron to aboveground photosynthetic organs is difficult. As a result, the synthesis of chlorophyll is inhibited and the productivity of agricultural plants decreases. Chlorosis is susceptible to crops in more than 30% of the area in soil conditions with a high content of carbonates. The most radical and common means of preventing and treating chlorosis are synthetic complexones. Forming mobile soluble complexes with iron, they significantly improve the transport of this metal in the plant. As complexons, as a rule, a number of aliphatic carboxyl-containing acids are used, such as citric, ethylenediamonetetraacetic (EDTA), diethylene triamine pentaacetic (DTPA).

 Closest to the proposed technical essence is a method for the prevention and control of calcareous chlorosis, which consists in a single treatment of plant root systems in the initial period of vegetation with a complex of iron with an organic ligand, and DTPA is used as an organic ligand. The acid used is characterized by the ability to form the most stable organic complexes with iron that are weakly dissociable in aqueous solutions. At the same time, complexes of DTPA with iron (Fe) are characterized by poor photochemical resistance. It is known that under the influence of ultraviolet radiation, these complexes decompose with the release of metal. In this case, in the case of using the most durable complexes of DTPA with ferric iron, photochemical reduction of the metal to a divalent form took place. A decrease in the oxidation state of Fe, as a rule, in any organic complex leads to a sharp decrease in its stability. For equimolar complexes of Fe with DTPA, this value is 11 orders of magnitude.

 The disadvantage of this method is the short duration of antichloric action, leading to insufficient efficiency in preventing plant chlorosis, due to the weak photochemical stability of DTPA and its participation in the photochemical reduction of oxide iron.

 The aim of the invention is to increase the efficiency of the method due to the prolongation of the antichloric action of iron in the organic complex.

This is achieved by the fact that in the known method for preventing carbonate chlorosis of plants, which consists in a single treatment of the root systems of plants of the initial vegetation period with an iron complex and an organic ligand, in accordance with the proposed invention, 1-hydroxyethylidene diphosphonic acid (HEDP) in equimolar ratio with iron taken in a concentration of (0.4-1) ˙10 ^-4 mol for hydroponic conditions and at a dose of 15-75 kg / ha for soil conditions.

 The essence of the invention lies in the fact that, unlike DTPA, the complexone OEDP does not phytochemically restore ferric iron, which ensures greater stability of its complexes in the aboveground organs of plants and a longer duration of the antichloric effect of iron. The indicated property was established by the authors, the concentrations of the drug introduced were determined empirically. In view of this, the claimed technical solution meets the criteria of novelty and materiality of differences.

 Data on the participation of HEDP in photochemical redox reactions of iron were obtained in the study of aqueous solutions of complexonates (pH 3.3) (Table 1). Iron was introduced based on the element 4 mg / l, complexones were used in an equimolar ratio with the metal. The forms of iron in solutions were determined colorimetrically using 0-phenanthroline after irradiation for 30 minutes with ultraviolet radiation.

 From the data table. 1, it follows that, unlike DTPA, the OEDP complexon acts as an oxidizing agent with respect to iron, and its complexonates are photochemically more stable.

 It is known to use OEDP as a component of complex micronutrient fertilizers for foliar plant nutrition in order to stabilize the composition and increase the biological value of the fertilizer. However, the experiments of the authors of this application to identify the biological value of HEDP in the complex with ferrous iron during foliar treatment of chlorinating plants showed a complete absence of the antichloric effect of this complex (Table 2).

 It is assumed that this nature of the effect is associated with the high photochemical strength of the complexes of iron with HEDP, which, if used during spraying, does not allow plants to utilize iron directly in the leaf mesophyll.

The duration of the antichlorous effect of iron-containing complexes of OEDP was radiated by the example of barley and sunflower under hydroponic conditions. Plant nutrition with equimolar iron complexes with organic ligands was carried out for 5-7 days. The concentration of complexones is 4˙10 ^-5 mol. At the end of this period, the seedlings were placed on a nutrient mixture (Knopp solution) without organo-iron complexes (conditions of Fe-stress). After 15 days, the content of chlorophyll and iron in the leaves was determined; after 1 month after the start of the experiment, the mass of aboveground organs and plant roots was measured (Table 3).

 As follows from the data table. 3, the antichlorous aftereffect of OEDP turned out to be the longest, ensuring the stability of the synthesis of chlorophyll for a long period of fasting plants through iron. At the same time, a short-term treatment of the roots of barley seedlings turned out to be quite enough to subsequently bring the grain crop to the heading stage with an absolute absence of iron in the nutrient medium. The treatment of young plants with iron complexes with DTPA and citric acid, which is widely used in hydroponics, was ineffective: during the period of Fe stress, there was a significant lag in plants in growth and severe leaf chlorosis, accompanied by necrosis of plant tissue.

 According to the data obtained, the Fe content in the leaves formed during the Fe-stress period was higher when using HEDP (Table 3), which indicates a longer participation of this complexon in the translocation of endogenous iron from roots to aboveground compared with DTPA and citrate. photosynthetic organs.

 The results of similar studies on the example of sunflower are presented in table. 4.

 The data obtained confirm the advantages of the antichlorous action of Fe - HEDP as compared with the prototype revealed in experiments with barley.

 The study of the effect of the concentration of iron complexonates on the content of chlorophyll in barley leaves is shown in table. 5.

 The concentration of iron in the nutrient solution ranged from 0.5 to 2.0 mg / L. The ratio of ligand to iron in the complex is equimolar. In contrast to the plant nutritional scheme, in studies of the duration of the antichlorous action of iron-containing complexes of HEDP (Table 3), root systems were supplied with iron complexones continuously during the growing season.

 It has been established that the introduction of OEDP into iron complexes allows plants to use this metal from the nutrient medium much more efficiently. So, in the case of the use of even insignificant amounts of iron (0.5 mg / l) in the form of a complex with HEDP, the content of chlorophyll in barley leaves did not differ from this indicator with a 4-fold excess of the concentration of iron in the solution. The minimum concentration of iron in solution in complex with DTPA caused plant chlorosis.

 Studies of the influence of HEDP on crop productivity under soil conditions were carried out in experiments with oats of the Borrus variety and spring rape on calcareous sod-podzolic soils of different mechanical composition (Table 6). The efficiency of HEDP (application rate of 45 kg / ha) was the highest, which provided an additional 10-18% increase in the yield of dry plant mass compared with the control.

The method is as follows. The root treatment of plants is carried out at the beginning of their vegetation with aqueous solutions of the Fe-OEDP complex. The ratio of metal to ligand in the complex is equimolar (1: 1). The salt of sulfate oxide (ferrous) iron is introduced at the stage of preparation of the complex by mechanical mixing with acid. The solution of the required concentration has, as a rule, high acidity (pH≈3.0-3.3), therefore, the nutrient solution is neutralized with potassium hydroxide to pH values optimal for plants ≈ 5.5-6.0, for hydroponics a nutrient solution with a concentration of HEDP and iron at (0.4-1) ˙10 ^-4 mol.

 When the complex is introduced into the soil, its neutralization is not carried out, and the acid is applied at a dose of 15-75 kg / ha. The complexes are used in the form of aqueous solutions with a concentration not exceeding 0.5% for the active substance.

PRI me R 1. Carry out measures to prevent chlorosis of annual ryegrass multiaxial when grown in soil conditions. Soil - calcareous sod-podzolic medium loamy. The effectiveness of antichloric exposure is estimated by the yield of dry weight (g / m ² ) and the content of chlorophyll (mg / g of wet weight). Prepare an aqueous solution of the complex Fe - OEDP based on the introduction of acid in a dose of 1 kg / ha. At the beginning of the growing season, the plant is treated with a nutrient solution, the concentration of the active substance in which is 0.5%. The dry mass yield is 64.0 g / m ² , the chlorophyll content is 4.9 mg / g wet weight.

PRI me R 2. Carry out measures to prevent chlorosis of ryegrass as in example 1. The dose of the introduced acid is 15 kg / ha. Prepare a nutrient solution (an aqueous solution of the complex Fe - OEDP) as in example 1, which is treated with plants. The dry mass yield is 67.0 g / m ² , the chlorophyll content is 5.5 mg / g wet weight.

PRI me R 3. Measures were taken to prevent chlorosis as in example 1. The dose of OEDP introduced acid was 45 kg / ha. The dry mass yield was 70.5 g / m ² , the chlorophyll content was 6.3 mg / g wet weight.

PRI me R 4. Carry out measures to prevent chlorosis as in example 1. The dose of the introduced acid OEDP - 75 kg / ha The dry mass yield is 69.0 g / m ² , the chlorophyll content is 6.4 mg / g wet weight.

PRI me R 5. Carry out measures to prevent chlorosis as in example 1. The dose of the introduced acid OEDP - 100 kg / ha The dry mass yield is 65.0 g / m ² , the chlorophyll content is 6.4 mg / g wet weight.

PRI me R 6. Carry out a control experiment, cultivating ryegrass without the use of complex Fe - HEDP. The dry mass yield is 64.0 g / m ² , the chlorophyll content is 4.9 mg / g wet weight.

From the above examples, it follows that the positive effect of HEDP on the synthesis of chlorophyll in ryegrass leaves remains in a wide range of concentrations, however, the highest productivity of the culture was obtained in the acid dose range from 15 to 75 kg / ha. At a dose of HEDP less than 15 kg / ha, the analyzed data on the yield and chlorophyll content do not differ from those for the control experiment. The smallest significant difference for the 5% significance level in examples 1-6 of NDS _0.5 is for the yield indicator 1.5 g / m ² , and for chlorophyll 0.4 mg / g wet weight, which indicates the reliability of differences between the obtained values from the control when introducing doses of HEDP in the range of 15-75 kg / ha.

PRI me R 7. Carry out a study of the effectiveness of the complex Fe - OEDP for hydroponic conditions. Plant nutrition with equimolar iron complexes with HEDP was carried out for 7 days, after which plant seedlings (barley) were transferred to a nutrient medium without organometallic complexes. The duration of antichlorous action is evaluated by the productivity of the culture. Set the dose of HEDP equal to 2˙10 ^-5 mol, maintain the pH of the solution 5.5-6.0. The mass of the aerial organs of the plant after 30 days is 2.0 g / vessel.

PRI me R 8. Investigate the effect of HEDP on the development of barley as in example 7, under conditions of hydroponics. The concentration of HEDP in the solution is 4˙10 ^-5 mol. The mass of the aerial organs of plants after 30 days is 2.6 g / vessel.

PRI me R 9. Investigate the effect of HEDP on the development of barley as in example 7, under hydroponic conditions. The concentration of HEDP is 1˙10 ^-4 mol. The mass of aboveground organs is 2.6 g / vessel after 30 days of cultivation.

PRI me R 10. Investigate the effect of OEDP on the development of barley as in example 7. The concentration of OEDP 2-10 ^-4 mol. The mass of the aerial organs of plants after 30 days is 2.4 g / vessel, inhibition of the root system of the plant is noted.

In examples 7-10 of the NDS _{05 of the} experiment is 0.15 g / vessel, which indicates the significance of differences in the weight of the aboveground organs in the experiments.

PRI me R 11. Explore the possibility of inhibiting the root system of a plant on agar-agar when using HEDP on the example of spring rape roots. HEDP introduced into the solution at a concentration 2˙10 ^-4 mol. After 6 days, the root length is 56 mm.

 PRI me R 12. Cultivate on agar-agar according to the scheme of example 7 spring rape at a concentration of HEDP - 4-10 mol. The length of the roots is 66 mm.

 PRI me R 13. Cultivate under hydroponic conditions according to the scheme of example 7 spring rape, however, OEDP is not introduced (control experiment). After 6 days, the root length is 66 mm.

The smallest significant difference for the 5% significance level (NDS ₀₅ ) in experiments 11-13 is 6 mm, which indicates the reliability of the results.

 The technical and economic effectiveness of the proposed method compared to the known one consists in the fact that the use of HEDP increases the duration of the antichlorous effect of iron several times. The use of this acid allows you to grow crops on nutrient media with extremely low concentrations of iron, which helps to save nutrients and reduces the likelihood of contamination of crop products with excessive amounts of metal. Assessment of the growth of green mass of plants in the complete absence of iron in the nutrient medium is a value 2-3 times higher than this indicator for the prototype, which ensures high efficiency of the proposed method with intensive cultivation of crops.

Claims (1)

METHOD FOR REGULATING PLANT GROWTH, including treatment of plant root systems in the initial period of vegetation with a complex of iron with an organic ligand, characterized in that, in order to reduce plant carbonate chlorosis, 1-hydroxyethylidene diphosphonic acid in an equimolar ratio with iron in concentration is used as an organic ligand (0 , 4 - 1.0) · 10 ^-4 mol for hydroponic conditions or at a dose of 15-75 kg / ha for soil conditions.

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