A highly efficient nanocopper hydroxide activates plant immune resistance and confers tolerance to salt and drought stress in rice

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A highly efficient nanocopper hydroxide acts as a powerful inducer of plant immune resistance while simultaneously enhancing rice tolerance to salt and drought stress. By functioning as a nano-enabled elicitor, nanocopper hydroxide stimulates defense-related signaling pathways, antioxidant enzyme activities, and stress-responsive gene expression, leading to improved physiological resilience under adverse conditions. Its nanoscale properties enable better interaction with plant tissues, promoting efficient uptake and sustained activation of immune responses without causing toxicity. As a result, rice plants exhibit enhanced growth, reduced oxidative damage, and improved water-use efficiency under salinity and drought stress, highlighting the potential of nanocopper hydroxide as a sustainable tool for strengthening crop resilience in stress-prone agroecosystems.

#NanotechnologyInAgriculture #NanocopperHydroxide #PlantImmunity #RiceResearch #AbioticStressTolerance #SaltStress #DroughtStress #SustainableAgriculture #CropResilience #PlantDefense#WorldResearchAwards#ResearchAwards #AcademicAwards

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