Abstract
The use of high quality sowing material is the fundamental condition for good yielding of crop plants. One of new, unconventional methods of seed quality improvement is low-frequency variable magnetic field. It has been found that this physical factor has a favourable effect on seed germination, emergence and growth of many crop plants. The objective of the study was to determine the effect of low-frequency magnetic field (LFMF) on the germination of radish seeds, with particular emphasis on old seeds. The experimental material were seeds of 7 lots of radish cv. ‘Mila’, with germination capacity of 66.5–92.5%. The age of the seeds was from 1 to 8 years. Seeds from all the lots were treated with variable magnetic field with frequency of 50 Hz, at 3 doses of magnetic induction as follows: 0 (control), 30 and 60 mT for 30 seconds. Then, the seed germination energy and capacity were determined, as well as the length of the hypocotyl and of the
radicle of the seedling, dry weight of seedling, and emergence and mean time of emergence. The low frequency magnetic field exposure (30 and 60 mT) improved radish seed germination energy and capacity of every old seed lot. The increase of germination energy of old seeds amounted to 12.3–19.2%, and the increase of germination capacity was 5.8–10%. Magnetic field stimulation caused the increase of germination energy for 3 out of 4 seed lots of high quality but did not affect the improvement of germination capacity of those lots. No significant effect of magnetic field of seeds on the hypocotyl and radicle elongation was observed with the exception of 1 out of the 7 seed lots. For the 2 old seed lots out of the 3 total, magnetic field treatment caused the increase of emergence by 4.4–13.0%.
References
Aksenov S.I., Bulychev A.A., Grunina T.Y., Turovetskii V.B., 1996. Mechanisms of the action of a low-frequency magnetic field on the initial stages of germination of wheat seeds. Biophysics 41(4), 931–937.
Alexander M.P., Doijode S.D., 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 Gen. Res. Newslet. 105, 1–5.
Baskin C.C., Baskin J.M., 2001. Seeds: ecology, biogeography, and evolution of dormancy and germination. Academic Press, California, San Diego.
Dziwulska-Hunek A, Kornarzyński K., Matwijczuk A., Pietruszewski S., Szot B., 2009. Effect of laser and variable magnetic field stimulation on amaranth seeds germination. Int. Agrophys. 23, 229–235.
Grzesiuk S., Kulka K., 1981. Fizjologia i biochemia nasion. PWRiL, Warszawa.
Hernandez Aguilar C., Dominguez-Pacheco A., Carballo A.C. Cruz-Orea A., Ivanov R., Lopez Bonilla J.L., Valcarcel Montanez J.P., 2009. Alternating field irradiation effects on three genotype maize seed field performance. Acta Agrophys. 14(1), 7–17.
Hampton J.G., TeKrony D.M., 1995. Handbook of vigour test methods. ISTA.
Kornarzyński K., Pietruszewski S., Segit Z., Szwed-Urbaś K., Łacek R., 2004. Wstępne badania wpływu stałego i zmiennego pola magnetycznego na szybkość wzrostu kiełków pszenicy. Acta Agroph. 3, 521–528.
Kubisz L., Hołubowicz R., Gauza M., Li H., Hojan-Jezierska D., Jaroszyk F., 2012. Effect of low freguency magnetic field on germination of onion (Allium cepa L.) seeds. Acta Phys. Pol. A. 121, 49–53.
Martinez E., Carbonell M.V., Florez M., Amaya J.M., Maqueda R., 2009. Germination of tomato seeds (Lycopersicon esculentum L.) under magnetic field. Int. Agrophys. 23, 45–49.
Moon J.D., Chung H.S., 2000. Acceleration of germination of tomato seeds by applying AC electric and magnetic fields. J. Electrostat. 48, 103–114.
Pietruszewski S., 2000. Elektromagnes. Wzór użytkowy. UP RP, 108883, BUP, 11, 78–79.
Pietruszewski S., 2002. Wpływ pól magnetycznych i elektrycznych na kiełkowanie nasion wybranych roślin uprawnych. Techn. Agr. 1(1), 75–81.
Pietruszewski S., Kania K., 2010. Effect of magnetic field on germination and yield of wheat. Int. Agrophys. 24, 297–302.
Prokop M., Pietruszewski S., Kornarzyński K., 2002. Wstępne badania wpływu zmiennych pól magnetycznych i elektrycznych na kiełkowanie, plony oraz cechy mechaniczne korzeni rzodkiewki i rzodkwi. Acta Agroph. 62, 83-93.
Phirke P.S., Kubde A.B., Umbarkar S.P., 1996. The influence of magnetic field on plant growth. Seed Sci. Tech. 24, 375–392.
Rochalska M., 2002a. Pole magnetyczne jako środek poprawy wigoru nasion. Acta Agroph. 62, 103–111.
Rochalska M., 2002b. Poprawa jakości materiału siewnego za pomocą zmiennego pola magnetycznego. Doświadczenia polowe. Acta Agroph. 62, 113–126.
Rochalska M., Orzeszko-Rywka A., 2005. Magnetic field treatment improves seed performance. Seed Sci. Tech. 33, 669–674.
Rochalska M., Grabowska-Topczewska K., Mackiewicz A., 2011. Influence of alternating low frequency magnetic field on improvement of seed quality. Int. Agroph. 25, 265–269.
Soltani F., Kashi A., Arghavani M., 2006. Effect of magnetic field on Ocimum basilicum seed germination and seedling growth. Acta Hort. 723, 279–282.
Słodkowski P., Rekowska E., 2004. Efficiency of flat covers on yielding of some vegetable species grown for bunch harvest. Folia Univ. Agric. Stein., Agricult. 234 (93), 361–365.
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