Experimental Investigation of Effects of Magnetic Water on Germination and Growth Rate of Coriander (Coriandrum sativum) in ex-vitro Conditions

Dion Daniels; Luwin Tzib

doi:10.31695/IJASRE.2022.8.2.14

Authors

Dion Daniels Department of Science, University of Belize, Belize https://orcid.org/0000-0001-8092-6708
Luwin Tzib Department of Science, University of Belize, Belize

DOI:

https://doi.org/10.31695/IJASRE.2022.8.2.14

Keywords:

Magnetic field, Nakuru County Referral Hospital, Coriander, Germination

Abstract

A magnetic field can be macroscopic in nature (current in a wire) or microscopic (current due to electrons in atoms) and it affects all living organisms since it is naturally a component of our environment known as the geomagnetic field. Various researches have shown that a plant’s overall growth and development is affected either positively or negatively by a magnetic field. Research has also shown that magnetic fields can also influence plant’s growth by applying it directly or indirectly. A cost-effective method of applying an indirect magnetic field to a plant is by magnetic water treatment, which is done by exposing ordinary water to a magnetic field and then irrigating the plants. The objective of this research was to determine the effects of magnetic water on the germination and growth rate of coriander in ex vitro conditions. There were 11 different treatments in this experiment including the control, with five different magnetic field strengths and two different exposure times for each magnetic field strength. The germination rate was observed and recorded after two weeks, while growth rate measurements were made starting from the third week after planting. Results showed that magnetic water treatment did not influence germination, but had a positive effect on the growth rate of coriander.

References

Nisticò, R. (2017). Magnetic materials and water treatments for a sustainable future. Research on Chemical Intermediates, 43(12), 6911–6949.

Eşitken, A., & Turan, M. (2004). Alternating magnetic field effects on yield and plant nutrient element composition of strawberry (Fragaria x ananassa cv. camarosa). Acta Agriculturae Scandinavica, Section B - Soil & Plant Science, 54(3), 135-139.

Teixeira da Silva, J. & Dobránszki, J. (2014). Impact of magnetic water on plant growth. Environmental and Experimental Biology, 12, 137 -142.

Pang, F. & Deng, B. (2008). Investigation of changes in properties of water under the action of a magnetic field. Sci. China Ser. G: Phys. Mech. Astro. 51: 1621–1632.

Ali, Y., Samaneh, R., & Kavakebian, F. (2014). Applications of Magnetic Water Technology in Farming and Agriculture Development: A Review of Recent Advances. Current World Environment, 9(3), 695-703.

Camacho, J. & Sosa, V. (2013). Alternative method to calculate the magnetic field of permanent magnets with azimuthal symmetry. Revista Mexicana de Fisica, 59: 8-17.

Dhawi, F. (2014). Why Magnetic Fields are used to Enhance a Plant’s Growth and Productivity? Annual Research & Review in Biology, 4(6), 886-896.

Matwijczuk, A., Kornarzyński, K., & Pietruszewski, S. (2012). Effect of magnetic field on seed germination and seedling growth of sunflower. International Agrophysics, 26(3), 271-278.

Ulgen, C., Yıldırım, A. B., & Turker, A. U. (2017). Effect of Magnetic Field Treatments on Seed Germination of Melissa officinalis L. International Journal of Secondary Metabolite, 63-69.

Podsiadlo, C. & Skorupa, B. (2017). Impact of magnetized water on germination energy of seeds and weight of garden savory (Satureja hortensis l.), buckwheat (Fagopyrum esculentum l.), yellow lupine (Lupinus luteus l.) and winter rape (Brassica napus l.) seedlings. Polish Academy of Sciences

Experimental Investigation of Effects of Magnetic Water on Germination and Growth Rate of Coriander (Coriandrum sativum) in ex-vitro Conditions

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