RU2620647C1 - Method to promote growth and development of carrots - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: method of promoting the growth and development of carrot involves the treatment of seeds before sowing by soaking and the treatment of vegetative plants during development by spraying with a biologically active substance. The treatment of vegetative plants is carried out at least twice: the first - during the phase of 3-4 leaves; the second - at the beginning of root crops ripening. As the active substance, the 0.003% aqueous solution of pectin extracted from Sosnovsky hogweed (Heracleum sosnowskyi) is applied, the substance flow rate being 400 l/ha.

EFFECT: increasing germination and seed germination rate, increasing yield and fruit quality, increasing plant vitality, increasing preservation of root crops during winter storage.

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Description

The invention relates to the field of agriculture and can be used for growing carrots.

An urgent task when growing carrots is to increase its productivity and obtain environmentally friendly commercial products. To solve this problem, a variety of plant growth regulators are used in agricultural production.

The most important physiological processes of plants are determined by the hormonal regulation system. However, the synthesis and production of phytohormones is economically inefficient. This led to the creation of their natural analogues - plant growth regulators.

A known method of protecting potatoes and vegetables from diseases (RF patent No. 2083111), including the processing of potatoes, beans, onions, cabbage and tomato biologically active substance SILK in a dose of 4-10 g / ha for the active substance.

A known method of stimulating the growth and development of vegetable crops (patent RU 2480977, IPC A01C 1/06, A01C 1/08, A01G7 / 00, publ. 12/27/2012), including treating the seeds before sowing and / or vegetative plants with a biologically active substance, In this case, a 0.00002-0.2% aqueous solution of pectin isolated from duckweed Lemna minor L., or the floating potamogeton natans L., or the marsh cinquefoil Comarum palustre L., or callus tissue of the resin are used as a biologically active substance. common Silene vulgaris (Moench) Garcke.

The closest analogue is a method of stimulating the growth and development of canteen carrots (RF patent 2346421, IPC A01C 1/00, publ. 07/10/2008), including treating the seeds before sowing by soaking, treating vegetative plants during the development period by spraying with a biologically active substance, this as a biologically active substance using the drug Verva, extracted from woody fir fir by emulsion extraction method, containing acidic and neutral components of needles, characterized in that the seed treatment before sowing is carried out with a drug concentration of 0.2-2.0 mg / l for 24 hours two days before sowing, treatment of vegetative plants is carried out with a drug concentration of 20-40 mg / l in the phase of 3-4 true leaves and in the phase of the beginning of formation root crops at a rate of consumption of 400 l / ha.

These methods can stimulate the growth and development of plants, reduce the period of emergence of seedlings, increase the productivity and quality of vegetable crops, and therefore, the effectiveness of protection against diseases is preserved. The disadvantage of analogues is the lack of an experimentally selected optimal dose of a biologically active substance in the form of an aqueous solution of pectin isolated from Sosnowski hogweed for processing seeds and crops of carrots.

The technical result of the present invention is to expand the arsenal of biologically active substances in the form of an aqueous solution of pectin isolated from Sosnowski hogweed, used in agriculture to effectively stimulate the growth and development of carrots, using a specially selected and experimentally justified optimal dose for carrots grown in conditions Far North. The selected dose and consumption rate of a biologically active preparation provides increased germination, seed germination rate, increased yield and quality of fruits, increased plant viability, increased safety of root crops during winter storage.

The technical result is achieved in that in a method of stimulating the growth and development of carrots, including treating the seeds before sowing by soaking and treating vegetative plants during the development period by spraying with a biologically active substance, the plants are treated at least two times: the first - in the phase of 3-4 leaves : the second is the beginning of the ripening of root crops, according to the invention, as a biologically active substance, a 0.003% aqueous solution of pectin isolated from Sosnowski hogweed (Heracleum sosnowskyi) is used, while the p waste of the drug is 400 l / ha.

Carrot cultivation in the Komi Republic is concentrated in the farms of the central and southern zones of the republic. To obtain stable quality crops, it is important to increase the adaptive capacity of plants in extreme conditions, including preserving fruits in the winter, which can be created by climatic factors. It is known that at the initial stage of development, carrot plants are more susceptible to stressful situations (Kolmykova TS, Lukatkin AS, Effectiveness of plant growth regulators under the action of abiotic stress factors // Agrochemistry. 2012. No. 1. P.83-94 ) So, on heavy sod-podzolic soils of the Komi Republic due to lack of moisture in the soil and low temperature, the period of swelling of carrot seeds is prolonged and there is an uneven emergence. Therefore, to increase the adaptation of plants, it is necessary to influence their initial phase of development. The most promising method of enhancing the biological processes occurring in the seed is their treatment with solutions of biologically active substances (Ludilov V.A., Alekseeva K.L. et al. Methods of presowing preparation of seeds of vegetable crops (recommendations). - M., 2000. - S.5-10). Biologically active substances are capable of having a negligible amount of stimulating effect on the course of physiological processes, affect the vital processes of plants, photosynthesis. Influencing metabolism, growth regulators contribute to the growth and development of plants, stimulating immunity, and resistance to many diseases of fungal, bacterial and viral origin (Prusakova L.D., Malevannaya N.N. et al. Plant growth regulators with anti-stress and immunoprotective properties / / Agrochemistry. 2005. No. 11. P.76-86).

Plant polysaccharides are recognized as active regulators of plant growth and development (Ovodova R.G., Golovchenko V.V., Popov S.V., Ovodov Yu.S. The latest information on pectin polysaccharides // Bulletin of the Komi Scientific Center, Ural Branch of RAS. 2010. No. 3. P.37-45). They are part of plant cells in the form of biopolymers partially methyl-esterified by carboxyl, often in the form of sodium, calcium and magnesium salts. Together with other components of plant cell walls, they provide their strength and extensibility, protect plants from drying out, providing drought resistance and frost resistance, play a protective role in the relationship of plants with phytopathogens, and contribute to the elimination of damage and the plant's release from stress. Their macromolecules are decisive in seed germination and plant growth, in the ripening and storage of vegetables and fruits, and the structure can change significantly during plant growth and development. In this regard, it seems very promising to clarify the role of pectins in the regulation of growth and development of dining carrots. Of particular interest for the study is the Sosnovsky cow parsnip Heracleum sosnowskyi, which is a potential source of pectin polysaccharides (content up to 17%). Studying the structural features of the components of the cowberry, their chemical characteristics and obtaining valuable products can help develop the scientific basis for its processing, which in turn can help solve the problem of limiting the distribution and harmfulness of cowberry as an invasive invasive species. Pectins isolated from plant materials with a different structure of carbohydrate chains are obtained in a known manner (RF patent 2149642, IPC A61K 35/78, publ. 05.27.2000), in particular, Heracleuman with biologically active action was isolated from Sosnovsky’s cow parsnip (Ponomareva S.A., Golovchenko V.V., Patova O.A., Vityazev F.V., Ovodov Yu.S. Determination of the optimal method for the extraction of pectins from Sosnovsky’s cow parsnip Heracleum sosnowskyi // Materials of the report of the II All-Russian Conf. glycobiology "(July 7-11, 2014, Saratov). Saratov. 2014. P.78). The biological activity of pectins isolated from plant materials with a different structure of carbohydrate chains is described in well-known works (for example, Golovchenko V.V. Structural and chemical characteristics of physiologically active pectin polysaccharides. Abstract of dissertation for the degree of Doctor of Chemical Sciences, 2013).

The method is as follows.

The studies were carried out on the experimental field of the Federal State Budget Scientific Institution for Research and Development of the Republic of Komi in accordance with the Methodology of Field Experience in Vegetable Production (2011), and the Methodology of Physiological Research in Vegetable Production (1970). The energy assessment of the techniques was carried out in accordance with the “Methodological manual for determining energy costs in the production of food resources and feed for the conditions of the North-East of the European part of the Russian Federation” (1997).

Laboratory studies were carried out in the institute’s agrochemical laboratory: dry matter content, total sugars, carotene, nitrates — using the Ecotest-2000 nitrate liquid analyzer; sowing quality of seeds in accordance with GOST 12038-84, P 52171-2003.

The elements of the technology for cultivating carrots in the dining room of the zoned Shantene 2461 variety in the Komi Republic were the use of growth regulators: Heracleuman - pectin from Sosnovsky borschik (Heracleum sosnowskyi); Verva (for comparative analysis) is a preparation from Siberian fir (Abies sibirica Ledeb.), The active part of which is a mixture of sodium salts of triterpene acids.

Before sowing, the sowing qualities of carrot seeds (germination energy and germination) and their general infection with diseases were checked. For this, the seeds were kept for 12 hours in aqueous solutions of growth regulators. Then the seeds were germinated in Petri dishes at room temperature in 4 replicates of 100 pieces. The control was seeds treated with water.

The field experiment was carried out on the experimental field of the Federal State Budget Scientific Institution of Research and Development of Agricultural Sciences of the Komi Republic using the zoned variety Shantene 2461. The area of the accounting plot is 5 m ² . Four repetition. Two-line sowing, seed sowing rate of 800 thousand units / ha. The treatment of plants with the concentration of biological products shown in table 1 was carried out by spraying in the phase of 3-4 leaves and the beginning of maturation of root crops. Fluid consumption 400 l per hectare.

Biometric measurements and selection of plant samples for analysis was performed from each repetition (10 plants). Assessment of the quality of marketable carrots was carried out by taking into account the mass and determining the chemical composition: dry matter content by the thermostatic method (vegetable feed. Methods for determining the moisture content. GOST 27 548-97); total Sugars (Method for the determination of soluble carbohydrates according to Bertrand. GOST 26 176-84); carotene - according to I.K. Murri (A.V. Petersburg. "Workshop on agronomic chemistry"), nitrates - ionometrically (GOST 13496.19 - 86) using an Ecotest-2000 nitrate liquid analyzer.

On average, over the years of studies 2013-2015, the treatment of carrot seeds with biological products significantly increased germination energy (HCP ₀₅ - 1.7%) compared with seeds soaked in water (control) by 9.9-14.5% ( F _F.E. > F _F.T. ). Laboratory germination ranged from 72.2 (control) to 84.2%. Germination increased significantly (NDS ₀₅ - 5.2%), compared with soaking seeds in water, by 10.8% (Verva); by 12.0% (Heracles). Infection of seeds treated with biological products decreased to 0.3-1.8% (in the control 11.8%).

As a result of studies conducted in 2015, it was found that seed treated with biologics showed a tendency to increase the sowing rate to 91.0% (Heracleum sosnowskyi) and complete seed disinfection from fungal and bacterial infections.

Sowing carrots was carried out on May 22-26. On average, over the years of passing the development phases, the options practically did not differ. Table 2 shows the phenological observations, 2013-2015. The emergence of seedlings in the plots, where they sowed seeds treated with drugs, was noted on the 8-11th day, 3-4 days earlier than seeds soaked in water. Mass shoots in the control variant appeared later than the experimental variants by 3 days.

In 2013, the development of carrot plants and the accumulation of the mass of root crops was greatly influenced by the long dry period, as a result of which the onset of beam and technical maturity was delayed. Beam maturity occurred on days 79-87, and treatment of plants with Heracleuman and Verva biologics accelerated the onset of beam maturity by 4-5 days. In the growing season of 2014-2015 insufficient heat accumulation in July negatively affected the development of carrot plants and the accumulation of root crops. Beam maturity occurred on 68-71 days, and treatment of plants with biological products accelerated the onset of beam maturity by 3 days.

The length of the period from mass shoots to the beginning of technical maturity in the options was 84-90 days.

Table 3 shows the biometric indicators of carrot plants in the phase of beam maturity, 2013-2015.

Observations of the peculiarities of root crops growth showed that by the time of beam production (Table 3), plants treated with biological products, compared with the control sowing, had significant changes in the direction of increasing the number of leaves from 7.6 to 8.4 pcs .; plant height from 46.4 to 51.5 cm and root mass from 78.5 to 93.8 g.

Studies conducted in 2015 showed that the difference in the number of leaves ranged from 0.7 to 1.0 pcs. with NDS ₀₅ - 0.7. Plant height significantly increased in all experimental options compared with the control. Biological preparations positively influenced the mass accumulation of root crops. According to this indicator, the increase was 13.7 (Verva) - 26.2 g (Heracles) to control.

For the period of beam maturity accounting, the annual average plant density of the plants varied from 70.0 to 77.5 pcs / m ² according to the options.

Table 4 presents the biometric indicators of carrot plants in the phase of technical maturity, 2013-2015. In the phase of technical maturity (table 4), the height of the plants increased significantly compared with the control from 50.2 to 54.5 cm; root diameter - from 3.0 to 3.3 cm; root length - from 11.5 to 12.7 cm; the area of the largest sheet - from 271.4 to 345.2 cm ² ; elevated mass - from 40.8 to 53.2 cm. Processing of seeds and crops affected the increase in the mass of the root crop. The mass of the root crop increased by 10.6-27.1 g (a significant increase was noted in the version with Heracleuman).

An indicator of leaf productivity is the ratio of the mass of the root to the aerial mass. The leaves worked most efficiently in plants treated with Heracleuman, where 3.3 units of biological yield and 2.3 units of root crops were obtained per unit mass of leaves.

In 2015, the weight of the root crop increased in experimental versions by 2.9 (Verva) - 26.7 g (Heracleuman); the diameter of the root crop increased by 0.1-0.3 cm (F _f.e <F _ft ). From sowing seeds soaked in water (control), the length of the root crop was 10.4 cm. After treatment of plants with biological products, this indicator increased by 0.6-1.3 cm. All differences between pairs of these values were within the experimental error.

No diseases were detected by the years of the growing season. In 2015, damage was noted in carrot root crops by a carrot fly (Chamaepsila rosae, an insect of the Psilidae family) in the variants treated with Verva and Heraleuman preparations; damage during the harvesting of root crops was insignificant.

Table 5 shows the yield of root crops of carrots in the dining room, 2015.

In 2015, by the time of receiving early production (on the 70th day after mass seedlings), the yield of the options was 34.7- 42.0 t / ha and was the highest in the version with Heracleuman (table 5). Experimental options gave an increase in comparison with the control in terms of both early and total yields. For these indicators, there are no significant differences between the sample means.

According to the value of the total yield in the version with Heracleuman, the highest indicator was obtained - 46.9 t / ha. The use of this drug contributed not only to increase carrot yield, but also the marketability of root crops (80.2%).

Table 6 presents the average yield of root crops of carrots in the dining room in 2013-2015. Research results 2013-2015 showed that by the time of obtaining beam products (table 3), the weight of the root crop increased by 16.3-19.5% compared to the control. Productivity increased by 13.4-18.7%, respectively (table 6). A significant increase in yield was noted for all experimental options.

In the phase of technical maturity, the trend of an increase in the mass of the root crop (table 4) after the use of biological products remained. According to this indicator, the increase was 11.0-28.9%. The total yield (table 6) increased by 14.5-30.7%, respectively. A reliable yield increase for this option was 9.3 t / ha or 30.7%.

Table 7 presents the chemical composition of root crops, 2013-2015. On average for 2013-2015 the dry matter content in root crops (table 7) ranged from 11.8 (control) to 12.7% (Verva). Chemical analysis of root crops showed that the use of biological products significantly increased the content of carotene in the roots of carrots. A significant increase in sugars was noted only in the Heracleuman variant. The carotene content in all experimental variants averaged 10.8 mg%, in the control - 8.1 mg%; sugar content - 6.7%, in the control - 6.3%.

After treatments with biologics, the amount of nitrates ranged from 94.8 to 157.8 mg / kg and was within the MPC. There was a tendency to a decrease in nitrates in production, which was clearly manifested in the Heracleuman variant: there were 94.8 mg / kg at 189.7 mg / kg in the control.

The results of the 2015 studies showed that the experimental options with Heracleuman treatment in terms of solids content significantly exceeded the control version. Significantly increased carotene content in all experimental variants.

Table 8 shows the results of storing root crops of carrots in winter, an average of 3 years.

Root crops were stored from September to April (storage period was 200-232 days). Storage temperature 12-10 ± 1 ° C, air humidity 93-95%. The sample size is 5 kg of standard root crops of each variant in two replicates. Stored in bags of non-woven fabric. Take into account: natural decline, total loss of mass and types of diseases.

In April, when root crops exited the dormant state, black rot (pathogen Altemaria radicina M.Dr. et E.) was noted. The affected root apex tissues were black. Losses from the pathogen ranged from 1.3 to 8.2% (table 8).

No defeats of root crops by diseases in the variants with treatments with Heracleuman were found. Losses are mainly due to natural attrition.

The natural loss of root crops during storage ranged from 4.7 to 5.9%. Biological preparations positively influenced the preservation of root crops. The output of marketable products by options has increased significantly, compared with the control by 6.9-9.8%.

Thus, the use of a biostimulator in the form of an aqueous solution of pectin isolated from Sosnowski hogweed, in comparison with the control, contributed to an increase in yield and an improvement in the quality of carrot root crops. The treatment of plants with a biological product had a positive effect on the accumulation of carotene and sugars in root crops, on the reduction of nitrate content in them, and ensured better preservation of root crops during winter storage.

Claims (1)

A method of stimulating the growth and development of carrots, including treating the seeds before sowing by soaking and treating vegetative plants during the development period by spraying with a biologically active substance, treating the plants at least two times: the first - in the phase of 3-4 leaves; the second is the beginning of root crop ripening, characterized in that a 0.003% aqueous solution of pectin isolated from Sosnovsky cow parsnip (Heracleum sosnowskyi) is used as a biologically active substance, while the consumption rate of the drug is 400 l / ha.