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Biology and Biotechnology of Environmental Stress Tolerance in Plants, Volume 3
significantly. The plants grown from treated seeds had been observed to have
massive vegetative growth, but no significant effect was recorded in terms of
reproductive yield (Katsenios et al., 2020).
In another study, Razmjoo & Alinian (2017) treated cumin seeds to a
static magnetic field of varying strengths, i.e., 0, 150 mT, 250 mT, 500 mT,
and 1 T for 12 min. An enhancement in germination attributes and early
growth parameters was observed in all the treatments. They also reported
that the days to emergence as well as flowering and maturity had been short
ened along with increased chlorophyll and declined proline contents under
exposure to static magnetic field. Braga et al. (2020) evaluated the impact
of MF pretreatment on the germination of coffee seeds and hence, the seeds
were treated with the magnetic stimulus of 10 mT and 28 mT for 6 days.
They suggested that seed pre-magnetization process would be an inexpensive
and effective technique since there was an improvement in the germination
uniformity along with permeability of cellular membrane and activation of
antioxidant systems under exposure to both magnetic field intensities. The
exposure of an extremely low EMF of 0.03 μT with 10 Hz frequency for 30
minutes was found to improve germination percentage with a higher accu
mulation of antioxidant enzymes in germinating Foxtail millet seeds (Setaria
italica). The EMF treated seeds were recorded to enhance the germination
percentage by 93% with a 15.66% higher germination efficiency than the
untreated seeds (Ramesh et al., 2020). The impacts of magneto-priming on
germination and subsequent seedling growth, or associated changes have
been summarized and presented in Table 5.1.
5.2.2 IMPACTS ON PLANT GROWTH AND DEVELOPMENT
The germination and early seedling developmental stages are very critical
since these two stages ultimately determine the overall growth and develop
ment of crop plants and ultimately its productivity. In the context of current
challenges for agricultural sustainability and food security, optimizing the
exposure duration and dose or intensity of physical agents is very pertinent.
As such the researchers are continuously engaged to find out the impact of
physical treatments including magnetic exposure on crop growth particularly
during early stages.
The growth of the cucumber (Cucumis sativus) plant was found to
increase significantly when magnetically treated water was used for irriga
tion during the cultivation of seeds (Hirota et al., 1999). Further, magnetized