Study of the effect of pre-sowing electromagnetic impact on the development of primary root system of cotton seeds after different duration of storage. II. Mass of sprout and root

Minka Koleva; Kiril Sirakov

Minka Koleva

, Kiril Sirakov

Abstract: The effects of pre-sowing electromagnetic treatments of seeds from different crops are the subject of intensive research by many authors such as alternative technologies for ecologically clean agriculture. The aim of this research was to study the effect of pre-sowing electromagnetic treatment on the accumulation of fresh mass of root and sprout of seeds, stored for one and two years before treatment, of five Bulgarian cotton varieties - Chirpan-539, Trakia, Helius, Natalia and Nelina. The seeds of each variety were treated in five electromagnetic fields, with different intensity and duration of exposure. It was found that the selected values of controllable factors had stimulating effect on the mass of sprout, root and total mass of sprout and root of treated seeds. The sprout mass increased by 8.9-13.8%, the root mass - by 6.1-11.3%. The sprout and root total mass increased by 7.8 - 12.7% and the best treatment options were 1 [U = (8…5) kV, τ = (15…35) s] and 4 [U= (6…3) kV, τ = (5… 25) s]. The two-year period of storage, as a separate factor, determined significantly lower mass of sprout by 8.5%, of root by 10.1% and total mass of sprout and root by 8.9%, compared to the one-year period of storage. Compared to the corresponding untreated control of each storage period, the electromagnetic impact had a stimulating effect in both storage periods: for the mass of sprout - by 11.4-16.8% in options 1 and 5.3-10.4% in options 1 and 4, respectively for one- and two-year storage of seeds; for the root mass - by 5.1-16.1% in options 1 and 4 and by 2.7-8.1% in option 4; for the total mass of sprout and root - by 10.8-16.5% in option 1 and 4.5-9.1% in option 4. Variants with significant higher values than the control variant - Chirpan-539 variety, untreated seeds stored for one year, were reported only for seeds stored for one year. Higher sprout mass was found for Chirpan-539 variety, in option 5 [U=(4…2)kV, τ =(5… 25)s], while higher root mass and sprout and root total mass were found for Nelina variety, in options 1 [U=(8…5)kV, τ =(15…35)s], 2 [U=(6…3)kV, τ =(15…35)s] and 3 [U=(8…5)kV, τ =(5…25)s]. Compared to the corresponding of each variety and storage period untreated control stimulating effect of pre-sowing electromagnetic treatment was observed for all varieties, in both storage periods, except Nelina variety, in this variety positive results were only in one-year storage of seeds. Helius variety reacted most strongly positively to the pre-sowing electromagnetic treatment for the mass of sprout and the total mass of sprout and root of the seeds stored for one year. The total mass of sprout and root increased the most in options 1, 2 and 4 - by 38.6-48.5% compared to the relevant control. Variety Nelina reacted most positively for the mass of root during the one-year storage of seeds, in options 1, 2 and 3.

Keywords: cotton seeds; duration of storage; electromagnetic treatment; root mass; sprout and root total mass; sprout mass

Citation: Koleva, M. & Sirakov, K. (2024). Study of the effect of pre-sowing electromagnetic impact on the development of primary root system of cotton seeds after different duration of storage. II. Mass of sprout and root. Bulg. J. Agric. Sci., 30(4), 717–727

References: (click to open/close)

Aladjadjiyan, A. (2002). Study of the influence of magnetic field on some biological characters of Zea mays. J. Cent. Eur. Agric., 3(2), 89-94.
Aladjadjiyan, A. (2007). The use of physical methods for plant growing stimulation in Bulgaria. Journal of Central European Agriculture, 8(3), 369–380.
Aladjadjiyan, A. (2010). Influence of stationary magnetic field on lentil seeds. International Agrophysics, 24, 321-324.
Alexander, M. P. & Doijode, S. (1995). Electromagnetic field, a novel tool to increase germination and seedling vigour of conserved onion (Allium cepa L.) and rice (Oryza sativa L.) seeds with low viability. Plant Genet. Resour. Newslett.,104, 1-5.
Alvarez, J., Martinez, E., Carbonell, V. & Florez, M. (2019). Magnetic-time model for triticale seeds germination. Romanian Journal of Physics, 64(9-10), art. no. 822.
Alvarez, J., Martinez, E., Florez, M. & Carbonell, V. (2021). Germination performance and hydro-time model for magneto-primed and osmotic-stressed triticale seeds. Romanian Journal of Physics, 66(1-2), art. no. 801.
Atanasov, A. & Dochev, V. (2008). An approach for technological management of mineral fertilization of crops. Journal of Central European Agriculture, 9(1), 147-153.
Baluchi, H. & Mahdavi, M. (2004). Effects of electromagnetic fields on seed germination and early growth of annual alfalfa, barley, and barnyard grass sauce. Iranian Journal of Biology, 21(3), 437-435.
Bilalis, D., Katsenios, N., Efthimiadou, A. & Karkanis, A. (2012a). Investigation of pulsed electromagnetic field as a novel organic pre-sowing method on germination and initial growth stages of cotton. Electromagnetic Biology and Medicine, 31(2), 143-150.
Bilalis, D. J., Katsenios, N., Efthimiadou, A., Karkanis, A. & Efthimiadis, P. (2012b). Investigation of pulsed electromagnetic field as a novel organic pre-sowing method on germination and initial growth stages of cotton. Electromagnetic Biology and Medicine, 31(2), 143–150.
Bilalis, D., Kamariari, P. E., Karkanis, A., Efthimiadou, A., Zorpas, A. & Kаkabouki, I. (2013). Energy inputs, output and productivity in organic and conventional maize and tomato production, under Mediterranean conditions. Notulae Botanicae Horti Agrobo-tanici Cluj-Napoca, 41(1), 190–194.
Delibaltova, V. & Kirchev, H. (2010). Grain yield and quality of bread wheat varieties under the agroecological conditions of Dobroudja region. Bulg. J. Agric. Sci., 16(1), 17-21.
Domínguez-Pacheco, A., Hernández-Aguilar, C., Cruz-Orea, A., Carballo-Carballo, A., Zepeda-Bautista, R. & Martínez-Ortíz, E. (2010). Semilla de maíz bajo la influencia de irradiación de campos electromagnéticos. Rev. Fitotec. Mex., 33(2), 23-28.
Đukić, V., Miladinov, Z., Dozet, G., Cvijanović, M., Tatić, M., Miladinović, J. & Balešević-Tubić, S. (2017). Pulsed electromagnetic field – a cultivation practice used to increase soybean seed germination and yield. Zemdirbyste-Agriculture, 104(4), 345‒352.
Florez, M., Carbonell, M. & Martinez, E. (2004). Early sprouting and ﬁrst stages of growth of rice seeds exposed to a magnetic ﬁeld. Electromagnetobiol. Med., 23(2), 157–166.
Galland, P. & Pazur, A. (2005). Magneto reception in plants. J. Plant Res., 118(6), 371-389.
Ganeva, D., Sirakov, K., Mihov, M., Zahariev, S. & Palov, I. (2015). Influence of pre-sowing electromagnetic treatments and duration of storage on germination energy and laboratory germination of seeds from Bulgarian tomato varieties. INMATEH - Agricultural Engineering, Bucharest, Romania, 45(1), 43-50.
Нernández-Aguilar, C., Carballo-Carballo, A., Artola, A. & Michtchenko, A. (2006). Laser irradiation effects on maize seed field performance. Seed Sci. Technol., 34, 193-197.
Hernández, A. C. A., Domínguez-Pacheco, A., Carballo, C. A., Cruz-Orea, R., Ivanov, J. L., López, B. & Valcarcel, M. J. P. (2009). Alternating magnetic field irradiation effects on three genotype maize seed field performance. Acta Agroph., 14(1), 7-17.
Ivankov, A., Zukiene, R., Nauciene, Z., Degutyte-Fomins, L., Filatova, I., Lyushkevich, V. & Mildaziene, V. (2021). The effects of red clover seed treatment with cold plasma and electromagnetic field on germination and seedling growth are dependent on seed color. Appl. Sci., 11, 4676. https://doi.org/10.3390/app11104676.
Kasakova, A., Yudaev, I., Fedorishchenko, M., Mayboroda, S., Ksenz, N. & Voronin, S. (2018). New approach to study stimulating effect of the pre-sowing barley seeds treatment in the electromagnetic field. OnLine Journal of Biological Sciences, 18(2), 197-207.
Kasakova, A., Yudaev, I., Mayboroda, S., Taranov, M., Ksenz, N. & Chronyuk, V. (2019). Prospects for the use of stimulation by electric field of old cereal seeds. Asia Life Sciences, (1), 229-239.
Kirchev, H., Delibaltova, V., Yanchev, I. & Zheliazkov, I. (2012). Comparative investigation of rye type triticale varieties, grown in the agroecological conditions of Thrace valley. Bulg. J. Agric. Sci., 18(5), 696-700.
Kostov, K., Palov, I., Sirakov, K., Kuzmanov, E. & Zahariev, Sv. (2014). Effect of pre-sowing electric treatments of seeds on the yields of wheat varieties Enola and Kristy. Bulg. J. Agric. Sci., 20(6), 1526-1530.
Leelapriya, T., Dhilip, K. S. & Sanker Narayan, P. V. (2003). Effect of weak sinusoidal magnetic field on germination and yield of cotton (Gossypium spp.), Electromagn. Biol. Med., 22(2-3), 117-125. https://www.emf-portal.org/en/article/10676.
Moon, J. D. & Chung, H. S. (2000). Acceleration of germination of tomato seed by applying AC electric and magnetic fields. J. Electrostatics, 48, 103-114.
Palov, I., Stefanov, St., Sirakov, K., Bozhkova, Yu. & Valkova, N. (1994). Possibilities of the pre-sowing electromagnetic treatments of cotton seeds. Agricultural Engineering, XXXI (6-7), 3-6 (Bg).
Palov, I., Stefanov, St., Ganev, Hr., Zlatev, Zl. & Stankovski, M. (1995). Method for pre-sowing electromagnetic treatment of peanut seeds. Patent for Invention, No. 42681, A 01 C 1/00, A 01 C 7/04 (Bg).
Palov, Iv., Kuzmanov, E., Sirakov, K., Stefanov, St., Neykov, Y. (2012). Results from a preliminary research on the pre-sowing electromagnetic treatment of rape seeds. Agronomy Research, 10(1-2), Estonia, 335-340.
Palov, I., Sirakov, K., Kuzmanov, E. & Zahariev, Sv. (2013a). Results of preliminary laboratory studies after pre-sowing electric treatment of pea seeds. Agricultural Engineering, 4, 17-23 (Bg).
Palov, I., Genchev, S., Sirakov, K., Zahariev, St. & Kuzmanov, E. (2013b). Results of field studies after pre-sowing electromagnetic treatments of French maize hybrid seeds. Mechanization of Agriculture, 1, 32-34 (Bg).
Savage, W. E. & Bassel, G. W. (2016). Seed vigour and crop establishment: extending performance beyond adaptation. Journal of Experimental Botany, 67(3), 567–591.
Sirakov, K., Ganeva, D., Zahariev, S., Palov, Iv. & Mihov, M. (2016). Study of laboratory germination of seeds from tomato variety Milyana after electromagnetic treatment. INMATEH - Agricultural Engineering, Bucharest, Romania, 48(1), 53-60.
Sirakov, K., Stoilova, A., Palov, I. & Muhova, A. (2018). Studying the effect of pre-sowing electromagnetic treatment on the lengths of roots and sprouts of triticale seeds the cultivar Boomerang. World Science, 1(29), 2, 10-17.
Sirakov, K., Álvarez, J. & Muhova, A. (2021). Evaluation of the effect of electromagnetic treatment on the sowing qualities of triticale seeds. Bulg. J. Agric. Sci., 27(4), 699-711.
Vashisth, A. & Nagarajan, S. (2008). Exposure of seeds to static magnetic field enhances germination and early growth characteristics in chickpea (Cicer arietinum L.). Bioelectromagnetics, 29(7), 571-578.
Zahariev, St., Sirakov, K., Palov, I. & Kuzmanov, E. (2013). Results of laboratory tests after pre-sowing electromagnetic treatments of seeds of French corn hybrid. Mechanization of Agriculture, 1, 29-31 (Bg).
Zahariev, Sv. (2015). Optimization of pre-sowing electric treatment of seeds. Dissertation, Ruse, Bulgaria.

Date published: 2024-08-27

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