Wpływ wody uzdatnianej magnetycznie na kiełkowanie i wzrost siewek łubinu wąskolistnego (Lupinus angustifolius L.)

Tomasz Stankiewicz; Kamila Kozak; Janusz Podleśny; Stanisław Pietruszewski

doi:10.24326/aspta.2012.1-2.3

Vol. 11 No. 1-2 (2012)

Artykuły

Influence of magnetically treated water on germination and seedlings development of narrow-leaf lupine (Lupinus angustifolius L.)

Tomasz Stankiewicz⁺⁻
Kamila Kozak⁺⁻
Janusz Podleśny⁺⁻
Stanisław Pietruszewski⁺⁻

pdf (Język Polski)

DOI: https://doi.org/10.24326/aspta.2012.1-2.3
Submitted: April 15, 2022
Published: 2022-04-15

Abstract

The research in this paper were conducted to presents the impact of magnetically treated water on the seeds germination of narrow-leaf lupine, and next on morphological diversity of seedlings in their early stages of development. The magnetic water treatment was conducted by means of a measuring system where the water flowed through a teflon tube placed between direct current electromagnet pole pieces. Water was passed between the electromagnet pole pieces for induction of direct current electromagnet field pieces B = 100 mT, 300 mT, 600 mT i 900 mT. The highest germination capacity of lupine seeds was reached after using induction of 300 mT. This same induction of magnetically treated water additionally improved the values of root/shoot ratio, stimulated seedling weight and number of leaves. The obtained results for the laboratory experiments may also have importance for the later development stages of plant, so it important to continue resarches with influence of magnetically treated water for growth and yield of plant on the field condition.

References

Apasheva L.M., Lobanov A.V., Kamissarov G.G., 2006. Effect of alternating electromagnetic field on Elary stages of plant development, Dokl. Biochem. Biophys. 406, 1–3.
Chen Y., Yuea M., Wanga X., 2005. Influence of He–Ne laser irirradiation on seeds thermodynamic parameters and seedlings growth of Isatis indogotica. Plant Sci. 168, 601–606.
Drozd D., Szajsner H., 1997. Laboratoryjna ocena wczesnych faz rozwojowych pszenicy jarej poddanej działaniu promieniowania laserowego. Biul. IHAR, 204, 187–190.
Goldsworthy A., 2006. Effects of electrical and electromagnetic fields on plants and related topics. In: Volkov, A.G. (ed.), Plant electrophysiology – theory and methods, Springer Verlag, Berlin Heidelberg 2006, 247–267.
Harris R.W., 1992. Root shoot ratios. J. Arboricult. 18(1), January, 39–42.
Khristyuk V.T., 2009. Effect of a Low-Frequency Electromagnetic Field on Growth and Malt quality of brewer’s barley. Russ. Agric. Sci., 35 (6), 429–431.
Kornarzyński K., Pietruszewski S., Podleśny J., 2006. Próba oszacowania wpływu namagnesowanej wody na kiełkowanie nasion roślin uprawnych. W: Oddziaływanie pól elektromagnetycznych na środowisko rolnicze. AR Lublin, 131–133.
Kornarzyński K., Pietruszewski S., 2011. Wpływ wody uzdatnianej magnetycznie na kiełkowanie nasion grochu i łubinu. Acta Agrophysica, 18 (1), 101–110.
Ling T.G., Liu L., Yang Z.Q., Shao S.X., Wang S.S., Sirigina M.T., Simakina L.V., 1992. The effect of gradient magnetic fields on crop yield and studies on its mechanism. Acta Agriculturae Univ. Pekin. 18, 357–362.
Monk C.D., 1966. Ecological importance of root/shoot ratios. Bull. Ton-ey Botanical Club 93, 402–406.
Morejon L.P., Castro Palacio J.C., Velazquez Abad L., Govea A.P., 2007. Simulation of Pinus Tropicalis M. seeds by magnetically treated water. Int. Agrophysics, 21, 173–177.
Phirke P.S., Patil M.N., Umbarkar S.P., Dudhe Y.H., 1996. The application of magnetic treatment to seeds: methods and responses. Seed Sci.& Technol., 24, 365–374.
Phirke P.S., Umbarkar S.P., 1998. Influence of magnetic treatment of oilseed on yield and dry matter. PKV – Res. J. 22, 130–132.
Pietruszewski S., Kornarzyński K., Łopucki M., 2007. Woda magnetyczna, jej niektóre właściwości fizyczne i zastosowanie. Przegląd Telekomun., 80, 8–9, 675–682.
Podleśny J., 2000. Wpływ światła laserowego na niektóre zmiany biochemiczne i fizjologiczne w nasionach i roślinach łubinu białego (Lupinus albus L.). Pam., Puł., 121, 171–191.
Podleśny J., Gendarz M., 2008. Wpływ wody uzdatnianej magnetycznie na wzrost, rozwój i plonowanie dwóch genotypów grochu siewnego. Acta Agrophysica, 12(3), 767–776.
Podleśny J., Pietruszewski S., 2009. Wpływ wody uzdatnionej magnetycznie na wzrost, rozwój i plonowanie dwóch genotypów bobiku. Annales UMCS, Sec. E, Agricultura, 64, 1, 52–58.
Rochalska M., 2002. Pole magnetyczne jako środek poprawy wigoru nasion. Acta Agrophysica, 62, 103–111.
Rochalska M., 2003. Wpływ pola magnetycznego na nasiona i rośliny. Post. Nauk Roln. 1, 31–46.
Rokhinson E., Gak E., Klygina L., 1994. Agricultural magnetic treatment of seeds and water. Int. Agrophysics, 8, 305–310.

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Keywords

magnetically treated water
seed germination capacity
magnetic field
seedlings development
narrow-leaf lupine

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[1] Apasheva L.M., Lobanov A.V., Kamissarov G.G., 2006. Effect of alternating electromagnetic field on Elary stages of plant development, Dokl. Biochem. Biophys. 406, 1–3.

[2] Chen Y., Yuea M., Wanga X., 2005. Influence of He–Ne laser irirradiation on seeds thermodynamic parameters and seedlings growth of Isatis indogotica. Plant Sci. 168, 601–606.

[3] Drozd D., Szajsner H., 1997. Laboratoryjna ocena wczesnych faz rozwojowych pszenicy jarej poddanej działaniu promieniowania laserowego. Biul. IHAR, 204, 187–190.

[4] Goldsworthy A., 2006. Effects of electrical and electromagnetic fields on plants and related topics. In: Volkov, A.G. (ed.), Plant electrophysiology – theory and methods, Springer Verlag, Berlin Heidelberg 2006, 247–267.

[5] Harris R.W., 1992. Root shoot ratios. J. Arboricult. 18(1), January, 39–42.

[6] Khristyuk V.T., 2009. Effect of a Low-Frequency Electromagnetic Field on Growth and Malt quality of brewer’s barley. Russ. Agric. Sci., 35 (6), 429–431.

[7] Kornarzyński K., Pietruszewski S., Podleśny J., 2006. Próba oszacowania wpływu namagnesowanej wody na kiełkowanie nasion roślin uprawnych. W: Oddziaływanie pól elektromagnetycznych na środowisko rolnicze. AR Lublin, 131–133.

[8] Kornarzyński K., Pietruszewski S., 2011. Wpływ wody uzdatnianej magnetycznie na kiełkowanie nasion grochu i łubinu. Acta Agrophysica, 18 (1), 101–110.

[9] Ling T.G., Liu L., Yang Z.Q., Shao S.X., Wang S.S., Sirigina M.T., Simakina L.V., 1992. The effect of gradient magnetic fields on crop yield and studies on its mechanism. Acta Agriculturae Univ. Pekin. 18, 357–362.

[10] Monk C.D., 1966. Ecological importance of root/shoot ratios. Bull. Ton-ey Botanical Club 93, 402–406.

[11] Morejon L.P., Castro Palacio J.C., Velazquez Abad L., Govea A.P., 2007. Simulation of Pinus Tropicalis M. seeds by magnetically treated water. Int. Agrophysics, 21, 173–177.

[12] Phirke P.S., Patil M.N., Umbarkar S.P., Dudhe Y.H., 1996. The application of magnetic treatment to seeds: methods and responses. Seed Sci.& Technol., 24, 365–374.

[13] Phirke P.S., Umbarkar S.P., 1998. Influence of magnetic treatment of oilseed on yield and dry matter. PKV – Res. J. 22, 130–132.

[14] Pietruszewski S., Kornarzyński K., Łopucki M., 2007. Woda magnetyczna, jej niektóre właściwości fizyczne i zastosowanie. Przegląd Telekomun., 80, 8–9, 675–682.

[15] Podleśny J., 2000. Wpływ światła laserowego na niektóre zmiany biochemiczne i fizjologiczne w nasionach i roślinach łubinu białego (Lupinus albus L.). Pam., Puł., 121, 171–191.

[16] Podleśny J., Gendarz M., 2008. Wpływ wody uzdatnianej magnetycznie na wzrost, rozwój i plonowanie dwóch genotypów grochu siewnego. Acta Agrophysica, 12(3), 767–776.

[17] Podleśny J., Pietruszewski S., 2009. Wpływ wody uzdatnionej magnetycznie na wzrost, rozwój i plonowanie dwóch genotypów bobiku. Annales UMCS, Sec. E, Agricultura, 64, 1, 52–58.

[18] Rochalska M., 2002. Pole magnetyczne jako środek poprawy wigoru nasion. Acta Agrophysica, 62, 103–111.

[19] Rochalska M., 2003. Wpływ pola magnetycznego na nasiona i rośliny. Post. Nauk Roln. 1, 31–46.

[20] Rokhinson E., Gak E., Klygina L., 1994. Agricultural magnetic treatment of seeds and water. Int. Agrophysics, 8, 305–310.