Authors :
Sumaiya Bano; Kanchan Awasthi; Madhu Prakash Srivastava; Neeraj Jain
Volume/Issue :
Volume 9 - 2024, Issue 7 - July
Google Scholar :
https://tinyurl.com/5fywsdc5
Scribd :
https://tinyurl.com/mr4y3fnt
DOI :
https://doi.org/10.38124/ijisrt/IJISRT24JUL1210
Abstract :
Eggplant (Solanum melongena L.) is an
economically significant crop, valued for its culinary
versatility and nutritional content. Understanding the
factors that influence its growth is crucial for optimizing
agricultural practices and improving yield. Zinc, an
essential micronutrient, plays a vital role in various
physiological processes within plants, including enzyme
activation, photosynthesis, and hormone regulation. This
study investigated the effect of zinc supplementation on
the growth parameters of eggplant.
The experiment was conducted in Botany Lab of
Maharishi University of Information Technology,
Lucknow in earthen Pots filled with garden soil. Where
eggplant seedlings were subjected to different levels of
zinc supplementation. Parameters such as plant height,
leaf area, root development, and biomass accumulation
were measured at regular intervals over the growth
period. Results indicated a significant positive correlation
between zinc concentration and various growth
parameters of eggplant. Seedlings treated with higher zinc
concentrations, enhanced leaf expansion, and more
extensive root systems compared to those with lower or no
zinc supplementation. Furthermore, zinc-treated
eggplants displayed improved resistance to certain
environmental stressors, suggesting a potential role of
zinc in enhancing plant resilience. These findings
underscore the importance of adequate zinc supply in
promoting the growth and development of eggplant crops,
thereby contributing to higher yields and improved
agricultural sustainability. Further research is warranted
to elucidate the underlying mechanisms of zinc-mediated
growth enhancement in eggplant and optimize zinc
application strategies for maximum benefit.
Keywords :
Zinc, Solanum melongena, Germination, Growth Yield.
References :
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Eggplant (Solanum melongena L.) is an
economically significant crop, valued for its culinary
versatility and nutritional content. Understanding the
factors that influence its growth is crucial for optimizing
agricultural practices and improving yield. Zinc, an
essential micronutrient, plays a vital role in various
physiological processes within plants, including enzyme
activation, photosynthesis, and hormone regulation. This
study investigated the effect of zinc supplementation on
the growth parameters of eggplant.
The experiment was conducted in Botany Lab of
Maharishi University of Information Technology,
Lucknow in earthen Pots filled with garden soil. Where
eggplant seedlings were subjected to different levels of
zinc supplementation. Parameters such as plant height,
leaf area, root development, and biomass accumulation
were measured at regular intervals over the growth
period. Results indicated a significant positive correlation
between zinc concentration and various growth
parameters of eggplant. Seedlings treated with higher zinc
concentrations, enhanced leaf expansion, and more
extensive root systems compared to those with lower or no
zinc supplementation. Furthermore, zinc-treated
eggplants displayed improved resistance to certain
environmental stressors, suggesting a potential role of
zinc in enhancing plant resilience. These findings
underscore the importance of adequate zinc supply in
promoting the growth and development of eggplant crops,
thereby contributing to higher yields and improved
agricultural sustainability. Further research is warranted
to elucidate the underlying mechanisms of zinc-mediated
growth enhancement in eggplant and optimize zinc
application strategies for maximum benefit.
Keywords :
Zinc, Solanum melongena, Germination, Growth Yield.