RU2731990C2 - Method for pre-plant treatment of potato tubers - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: method includes treatment of tubers with stabilized electrochemically activated catholyte with pH 7–9 and redox potential Eh=−400÷−500 mV, stabilized amino acid glycine in concentration 0.01 wt %, and containing Fe iron nanoparticles with size of 80 nm and silicon oxide of SiO₂ with size of 25 nm in weight ratio of 1:3. Concentration of Fe nanoparticles in the catholyte—16·10^-4 mol and SiO₂ nanoparticles—6·10^-3 mol under pressure of 9.8–14.7 Pa at installation with rotating drum with drum rotation frequency of 10 rpm, treatment time is 5 minutes.

EFFECT: method provides higher sprouting energy and emergence.

1 cl, 4 tbl

Description

The invention relates to agriculture and can find application in improving the technology of growing potatoes.

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

To accelerate the energy of germination and germination of potato tubers, as well as to increase its yield, pre-sowing electrical, physical and biological treatments are widely used [1, 2, 3].

During pre-sowing electrical stimulation of seeds of grain crops in the 40s of the XX century, the following phenomena were revealed: an increase in germination, an increase in both roots and leaf mass of plants, the development of early maturity, an increase in the productivity of crops and their quality [4, 5].

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 evolutionary and interrelated genetic, metabolic, hormonal, electrophysiological and other systems [6, 7, 8].

Classical experiments [9, 10, 11] have reliably established that any plant cell is characterized by an electric polarity. In this case, the inner part of the cell is negatively charged with respect to the external environment and the existing tension can reach up to 100,000 V / cm [12, 13]. 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 supported by the electromagnetic field of the earth and 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 electric current density reaches 4-8 μA / cm ² .

Our analysis of the results of scientific research [2, 3 ... 11, 12] on the pre-sowing treatment of seeds allowed us to formulate a direction in the development of the proposed method for processing potato tubers, the essence of which is the effect of "electrochemical activation" (ECA) on the tissue system and starchy protein mass , which in turn changed the bioelectric potential of the tuber.

Using the achievements of nanotechnology, the use of nanoparticles (NPs) when treating potato tubers together in a mixture with catholyte, as a doping to overcome negative effects [14], it is possible to significantly increase their energy of germination and germination [15, 16].

It is known that the lack of silicon inhibits the growth and development of plants. The conclusions of the world's leading scientists put forward the properties of silicon in first place [17]. With the improvement of silicon nutrition, the efficiency of photosynthesis and the activity of the root system increase [18].

The stimulating effect of iron nanoparticles on increasing the germination energy and seed germination is also known, which is confirmed by the results of studies [19, 20, 21].

Analogs - prototypes of the present invention is a method of seed treatment in a vacuum environment [21] using biologically active nanoparticles of iron and silicon oxide in a solution of catholyte [19].

To solve the problem of increasing the efficiency of the presented method, we combined their effect under pressure within 9.8-14.7 Pa (1.0-1.5 kgf / m ² ).

The analysis of available information sources did not reveal the use of iron nanoparticles Fe of the optimal dosage [23, 24] and NPs of silicon oxide SiO ₂ in a mixture with catholyte during treatment under pressure, as a method of biostimulation of germination of potato tubers. When this task was to establish the processing time and when LF optimal dosage SiO ₂ in combination with an optimum for low frequency Fe in the catholyte solution.

Thus, the claimed technical solution corresponds to the patentability "novelty".

The aim of the invention is to increase the germination energy and germination capacity of seed potatoes. The goal is achieved in that according to the proposed method tubers treated under pressure 9,8-14,7 Pa emulsions with Bass ECA catholyte Fe and SiO ₂ having a pH of 7-9 and a redox potential Eh = -350-450 mV, stabilized amino acid with glycine in an amount of not less than 0.001 wt. % on a unit with a rotating drum with a frequency of 10 rpm for 5 minutes.

In the experiment using nanoparticle Fe manufacturer of "advanced powder technology" Tomsk SiO ₂ and producer "Plazmoterm» Ul. Tarutinskaya, 1

To check the results of achieving this goal in our experiment, the presowing treatment of seed potato tubers, the germination of tubers was carried out in a growing chamber for 10-15 days.

The use of the proposed method of electrochemical activation of potato tubers makes it possible to exclude pre-planting germination of vernalization for 40-60 days, to make fuller use of the genetic potential inherent in the variety by intensive germination of a viable bud for 10-15 days.

For the experiment used

Potato variety Itzil (breeding number 03.9.7), selected from botanical seeds obtained from crossing the varieties Condor and Fresco in the potato breeding laboratory of the South Ural Research Institute of Horticulture and Potato Growing.

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

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

Our proposed stabilizer 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 not less than 0.01 wt. %, in our experiment glycine [25].

An aqueous solution of catholyte with a pH of 7-9 and a redox potential of 400-500 mV was obtained in the experiment by electrolyte tap water using the bioelectroactivator "Espero-1".

The initial data of the tap water used in the experiment corresponded to the requirements of SanPin 2.1.4.1074-01.

The experimental results are presented in table 2.

The calculation of the germination energy showed that the method of processing potatoes under a pressure of 9.8-14.7 Pa for 5 minutes gives an increase to the control, II and III options 22%, 32% and 42%, as well as all biometric indicators almost 2 times ...

Strong inhibitory germination was shown by the III treatment method up to 50%, the suppressing growth of sprouts up to 21.6%, and of roots up to 33.9%, in comparison with the I method of treatment, is especially clearly visible (Table 2).

According to variant I, the content of chlorophyll (a + b) and carotenoids exceeded the control, variants II and III, respectively, by 7.5-37.5%, by 26.6-50% (Table 3).

The change in metabolism is determined by the activity or isozyme spectrum of key enzymes - AO (antioxidants). The results of the experiment showed that a sharp increase in the enzymes superoxide dismutase (SOD) and catalase (CAT) in potato sprouts in comparison with the control was manifested with an increase in the processing time by 3.9-10.1% and 5.9-100%, respectively.

The product of LPO (lipid peroxidation) of membranes, malondialdehyde (MDA), is used as a biological indicator of the development of oxidative stress in plants. According to modern concepts, metal NPs contribute to the mechanical destruction of membrane structures, as a result of which changes the probability of the entry of metals into cells doubles. In the results of our studies, there is a decrease in MDA in treatment option I in comparison with the control, treatment methods II and III, which indicates the preservation of the integrity of cell membranes and, as a result, successful adaptation of plants to nanoparticles.

On the contrary, there was a slight decrease in phenolic compounds (PCs) in leaves and roots, and in all treatments. The tendency towards a decrease in PS upon exposure can be explained either by a low rate of synthesis of the studied group of substances, or by a weak manifestation of oxidative stress in seedlings, therefore, the lack of demand for PS as elements of AOS. Apparently, plants in an environment of NPs containing iron and silicon oxide fully cope with the “quenching” of ROS due to a decrease in the content of PSs due to their oxidation.

The use of peroxidase as a marker of a stress state makes it possible to more fully characterize defense pathways for diagnosing resistance to stress factors. When treating potato tubers with NPs Fe 16⋅10 ^-4 M and NPs SiO ₂ 3⋅10 ^-3 M, it was shown that the peroxidase activity in sprouts increased by 2 times in comparison with the control. Moreover, with increasing treatment time, a smaller increase in peroxidase activity was caused (Table 4).

таким образом увеличит урожайность на 20-25%, а также исключит длительность предпосадочного светового проращивания - яровизацию в течение 15-20 дней и расширит применимость способа выращивания картофеля в факторостатных лабораторных условиях.The given data testify to the high efficiency of the pre-planting method of processing potato tubers under a pressure of 9.8-14.7 Pa for 5 minutes according to option I. This method guarantees an increase in all morphometric and morphophysiological parameters of the model

thus, it will increase the yield by 20-25%, and also exclude the duration of pre-plant light germination - vernalization for 15-20 days and will expand the applicability of the method of growing potatoes in factorostatic laboratory conditions.

Compared with the treatment of potato tubers in a vacuum environment [22], when processing them under pressure, the germination energy indices were higher by 4%, the number of sprouts was higher by 9.3%, and the number of roots — by 24.5%.

Literature

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22. Application for invention RU No.: 2018127963 "Method for pre-planting treatment of seed potato tubers" authors Mushinsky A.A., Sizova E.A. et al., Registered August 01, 2018.

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Claims (1)

A method for preplanting potato tubers, including the treatment of tubers with a stabilized electrochemically activated catholyte with a pH of 7-9 and a redox potential Eh = -400 ÷ -500 mV, stabilized by the amino acid glycine at a concentration of 0.01 wt%, and containing iron nanoparticles Fe of size 80 nm and silicon oxide SiO ₂ of 25 nm in a weight ratio of 1: 3 at a concentration in the catholyte LF Fe 16⋅10 ^-4 mol, and the low SiO ₂ - 6⋅10 ^-3 mol pressure 9,8-14,7 Pa to install with a rotating drum with a drum rotation frequency of 10 rpm, processing time 5 min.