Energy dose of flax seed treatment in a magnetic field
DOI:
https://doi.org/10.31548/energiya2022.01.005Abstract
Pre-sowing treatment of flax seeds in a magnetic field makes it possible to improve seed sowing performance and increase flax yield without the use of mineral fertilizers and chemical plant protection products.
Compared to other electrophysical methods, pre-sowing seed treatment in a magnetic field is a highly productive, low-energy, safe method for service personnel and the environment.
It is now established that the yield and biometric indicators of crops depend on the dose of magnetic treatment.
Therefore, the aim of the study was to determine the optimal energy dose of flax seed treatment in a magnetic field.
An analytical expression for determining the energy dose of flax seed treatment in a magnetic field is obtained, which contains all the mode parameters of seed treatment. It is established that the energy dose of flax seed treatment in a magnetic field depends in direct proportion to the square of magnetic induction and polar division and inversely proportional to the velocity of seed movement in a magnetic field.
The conducted multifactorial experiment made it possible to determine the germination energy and germination of flax seeds at different energy doses of treatment. This made it possible to determine the optimal mode of flax seeds treatment in a magnetic field.
It is established that the optimal mode of pre-sowing treatment of flax seeds in a magnetic field is magnetic induction 0.065 T, four-fold re-magnetization, pole division 0.23 m, seed velocity 0.4 m/s, providing an energy treatment dose of 1.79 J · s/kg. With the optimal treatment of flax seeds in a magnetic field, germination energy increased by 30 %, germination - by 2 6%, stem length - by 10.5 %, straw yield - by 0.7 t/ha, seeds - 0.79 t ha.
Key words: flax, pre-sowing treatment, magnetic field, magnetic induction, pole division, velocity of seed movement, energy dose of treatment
References
Kutis, S.D., Kutis, T.L. (2017). Electromagnetic technologies in crop production. Part 1. Electromagnetic treatment of seeds and planting material. Moscow: Ridero, 49.
Spiridonov, A. B. (2013). Tekhnologiya drazhirovaniya semyan l'na-dolguntsa s ispol'zovaniyem nanoudobreniy i elektrofizicheskikh poley [Technology for coating fiber flax seeds using nanofertilizers and electrophysical fields]. Privolzhskiy nauchnyy vestnik. Izhevsk, № 10 (26), 48-50.
Iderawumi, A. M., Friday, C. E. (2020). Effects of magnetic field on pre-treament of seedlings and germination. Journal of Agriculture and Research (ISSN: 2455-7668), 6(9), 01-08. Retrieved from https://ijrdo.org/index.php/ar/article/view/3818
Nyakane, Neo E., Markus, E. D., Sedibe, M. M. (2019). The Effects of Magnetic Fields on Plants Growth: A Comprehensive Review. International Journal of Food Engineering, 5 (1), 79-87.
Purygin, P. P., Vasil'yeva, T. I., Purygin, V. A., Sovetkin, D. A., Tsaplev, D. A. (2015). Vliyaniye predposevnoy obrabotki semyan l'na na rost i biokhimicheskiye pokazateli prorostkov [Influence of presowing treatment of flax seeds on the growth and biochemical parameters of seedlings]. Vestnik SaMGU. Yestestvennonauchnaya seriya, 10(132), 166–173.
Cakmak, T., Cakmak, Z. E., Dumlupinar, R., Tekinay, T. (2012). Analysis of apoplastic and symplastic antioxidant system in shallot leaves: impacts of weak static electric and magnetic field. J. Plant Physiol., 169, 1066–1073.
Nizharadze, T. S. (2013). Vliyaniye ekologicheskikh priyemov predposevnykh obrabotok semyan yachmenya na porazhennost’ listosteblevymi boleznyami [The impact of environmental practices of presowing treatment of barley seeds on the incidence of leaf stem diseases]. Izvestiya Orenburgskogo gosudarstvennogo agrarnogo universiteta, 6 (44), 56-58.
Kozyrskyi, V., Zablodskiy, M., Savchenko, V., Sinyavsky, O., Yuldashev, R., Kalenska, S., Podlaski, S. Z. (2019). Magnetic Treatment of Water Solutions and Seeds of Agricultural Crops. Advanced Agro-Engineering Technologies for Rural Business Development. IGI Global, 256 – 292.
Adler, Yu. P., Markova, E. V, Granovskiy, Yu. V. (1976). Planirovaniye eksperimenta pri poiske optimal’nykh usloviy [Planning an experiment when searching for optimal conditions]. Moskow: Nauka, 278.
Kozyrskyi, V., Savchenko, V., Sinyavsky, O. (2018). Presowing Processing of Seeds in Magnetic Field. Handbook of Research on Renewable Energy and Electric Resources for Sustainable Rural Development. IGI Global, 576 – 620.
Pietruszewski, S., Martínez, E. (2015). Magnetic field as a method of improving the quality of sowing material: a review. Int. Agrophys, 29. 377-89.
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