RU2690937C1 - Method for pre-plant treatment of seed tubers of seed potatoes - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: method for pre-plant treatment of seed potatoes includes use of Fe and SiOnanoparticles in a suspension composition for treatment at their dosage respectively Fe nanoparticles 16⋅10 mol/l and SiOnanoparticles 6⋅10 mol/l in a mixture with a stabilized electrochemically activated aqueous catholyte with pH 8–9 and Eh=-400…-500 mV. Treatment is performed in vacuum medium at pressure of 650–680 mm of mercury with simultaneous mixing in drum with rotation frequency of 10 rpm for 5 minutes. Stabilizer used is glycine in amount of 0.01 wt%.EFFECT: invention provides increased sprouting energy and germinating capacity of seed potatoes.1 cl, 3 tbl

Description

The invention relates to agriculture and can be used to improve the technology of potato cultivation.

The purpose of the invention is to stimulate the growth and development of plants.

To speed up the germination energy and germination of potato tubers, as well as to increase its yield, pre-sowing electrical, physical and bioprocessing are widely used [1, 2, 3, 4, 5, 6, 7, 8].

When conducting pre-sowing electrical stimulation of seeds of grain crops in the 40s of the 20th century, the following phenomena were identified: increase in germination, increase in both the roots and leaves of plants, the growth of early ripening, increase in crop productivity and quality [9, 10].

In an intact plant organism, the formation of new tissues and organs that form the basis of plant growth and development are under the constant influence of evolutionarily established and interrelated genetic, metabolic, hormonal, electrophysiological and other systems [11, 12, 13].

Classical experiments [14, 15, 16] have reliably established that electrical polarity is inherent in any plant cell. At the same time, the inner part of the cell is negatively charged with respect to the external environment and the existing intensity can reach up to 100,000 V / cm [17, 18]. There is an electrical potential difference between the aboveground and underground mass of a plant during all periods of its growth and development, which is maintained by the electromagnetic field of the earth and the atmosphere. Moreover, the root in relation to the stem has a positive potential, the stem in relation to the root is negative. The constant voltage is in the range of 15-25 mV, and the density of electric current reaches 4-8 μA / cm ² .

Thus, in the well-known experiment, an increase in the soil environment of a positive charge led to an increase in the yield of corn grain by 4.7 centners per hectare; the wetted seeds in water contaminated with aeroins increased field germination by 14–16%, which is higher compared to the control - seeds, moistened with ordinary natural water [15].

Our analysis of the results of research [7, 8 ... 16, 17] on pre-sowing treatment of seeds in an electric field allowed us to formulate a direction in the development of the proposed method of processing potato tubers, the essence of which is the effect of "electrochemical activation" (ECA) on the tissue system and starch-protein mass, which in turn changed the bioelectric potential of the tuber.

Using the achievements of nanotechnology in the use of NPs in the treatment of seed material together in a mixture with catholyte, as a doping to overcome negative impacts [27], it is possible to significantly increase their germination and germination energy [28, 29].

It is known that the lack of silicon inhibits the growth and development of plants. The findings of the world's leading scientists put forward the properties of silicon in the first place [30]. With improved silicon nutrition, photosynthesis efficiency and activity of the root system increase [31].

Known and exciting effect of iron nanoparticles on the increase in germination energy and seed germination, confirmed by research results [32, 33, 34].

The analogue of the influence of ECT catholyte [31] is the electrical stimulation of seeds by treating them with aero ions of negative polarity, presented in the research by А.А. Chizhevsky [20].

To solve the problem of increasing the efficiency of application of the presented methods, we combined their influence with vacuum processing.

An analysis of the available information sources did not reveal the use of iron nanoparticles of optimal Fe [35, 36] and silicon SiO ₂ nanoparticles mixed with catholyte when processed in a vacuum environment, as a method of biostimulation of seed germination of seed potatoes. In this case, the task was to establish the optimal dosage of the use of SiO ₂ nanoparticles in combination with the optimal Fe for NP nanoparticles in a catholyte solution when processing tubers.

Thus, the claimed technical solution meets the patentability of "novelty."

The aim of the invention is to increase the germination energy and germination of seed potatoes. This goal is achieved by the fact that according to the proposed method, the tubers are processed in a vacuum environment at a pressure of 650-680 mm Hg. in an ECA emulsion catholyte with LF Fe, the optimal concentration is 16⋅10 ^-4 mol / l and SiO ₂ 6⋅10 ^-3 mol / l, respectively, with a pH of 8-9 and a redox potential Eh = -400… -500 mV, stabilized amino acid with glycine in the amount of 0.01 wt. % on the installation with a rotating drum with a frequency of 10 rpm for 5 minutes

In the experiment, Fe (II) nanoparticles were used: the manufacturer of Advanced Powders Technology, Tomsk, and SiO _{2, the} manufacturer of Plasmotherm, Moscow, ul. Tarutinskaya, 1

To test the results of achieving the goal in our experiment, pre-sowing treatment of tubers of seed potatoes, the germination of tubers was carried out in a vegetation chamber for 10-15 days, which will be used in the cultivation of potatoes.

Using the proposed method of electrochemical activation of potato tubers eliminates preplant germination - vernalization for 40-60 days, make fuller use of the genetic potential inherent in the variety through intensive germination of a viable kidney for 10-15 days, which will find application in intensive potato cultivation technology.

For the experiment, the Potato Grade Itcil (selection number 03.9.7) was used, selected from botanical seeds obtained from crossing Condor and Fresco varieties in the laboratory of potato breeding at the South Ural Research Institute of Horticulture and Potato Farming.

The processing mode of potato tubers are presented in table 1.

For disinfection of potato tubers during their preparation for the experiment, they were treated with 0.01% potassium permanganate solution.

The stabilizer we offer demonstrates stable antimicrobial and antifungal activity, long-term preservation of the redox potential of the cathode aqueous solution and is an amino acid from the group of polar (hydrophilic) uncharged amino acids in an amount of 0.01 wt. %, in our experiment glycine [23].

An aqueous solution of catholyte with a pH of 8-9 and a redox potential of Eh = -400 ... -500 mV was obtained in the experiment by electrolyte tap water using the Espero-1 bio-electroactivator [22].

The initial data of the tap water used in the experiment met the requirements of SanPin 2.1.4.1074-01 [24].

In order to determine the effect of treating an ECA tuber with a catholyte, measurements were made of the voltage between the growth point (apical kidney) - negative polarity and umbilical cord of the tuber - positive polarity.

The results of the experiment are presented in table No. 2.

Thus, the proposed pre-planting method of treating tubers of seed potato ECHA with catholyte in a vacuum environment at a pressure of 650-680 kgf / cm according to option III (Table 1, 2) showed that germination energy on day 6 exceeded control, option I and II % - 18%, and the number of sprouts on a tuber on the 15th day of germination exceeded the figures by 17.2%, 10.4% and 6.9%, i.e. eliminates the duration of preplant light germination - vernalization for 15-20 days and extends the applicability of the method of growing potatoes in factorostat laboratory conditions.

The method is environmentally friendly and allows you to increase the maximum potential of the variety by increasing the polarity of the tuber and improving the technology of potato cultivation, which predetermine an increase in both the quality of the variety and the yield by 30-40% [7, 12].

Literature

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14. Izakov V.Ya., Rybin I.A. Biological phenomena in animals and plants. Basics of electrobiology. Sverdlovsk, USU, 1973.

15. Vorontsov D.S. Electricity in a living organism. "Knowledge", 1961.

16. Gunar I.I. the problem of plant irritability and its significance for the further development of plant physiology. Report at the scientific conference of the Academy. Timiryazeva, December 9, 1952. M., 1953.

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20. Chizhevsky A.L. Aeroionification in the national economy. M .: Gosplanizdat, 1960. p. 531-557.

21. Khasanova Z.M., Naumov L.G. Preseeding electrical seed treatment. Ufa, Bashkir book publishing house, 1981. 112 p.

22. Bakhir V.M., Zadorozhny Yu.G., Leonov B.I. and others. Electrochemical activation: water purification and obtaining useful solutions. M .: VNIIMT, 2001. 176 p.

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24. SanPiN 2.1.4.1074-01 Drinking water. Hygienic requirements for water quality of centralized drinking water supply systems. Quality control. - M .: Federal Center for Gossanepidnadzor of the Ministry of Health of Russia. 2002. 103 p.

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32. Patent RU No. 2635103. Posted 11/09/2017. Bul No. 31 (prototype)

33. Patent RU No. 2633471. Published 06/26/2017. Bul No

34. Patent RU No. 2627556. Posted 06/08/2017. Bul No

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table 2

Effect of seed potato processing regimes

Claims (1)

The method of preplant treatment of seed potato tubers, including the use of iron nanoparticles of Fe with a size of 80 nm and silicon nanoparticles of SiO _{2 with a} size of 25 nm and the optimum concentration of their Fe 16 ⋅ 10 ^-4 mol / l NP and SiO ₂ 6 ⋅ 10 ^-3 mol / l NP in a mixture with stabilized electrochemically activated water catholyte with a pH of 8-9 and Eh = -400 ... -500 mV in a vacuum medium at a pressure of 650-680 mm Hg. with simultaneous stirring in a drum with a rotational speed of 10 rpm for 5 min, while the stabilizer used is an amino acid from the group of polar uncharged amino acids, which is glycine, in an amount of 0.01 wt. %