Description
Book SynopsisSignificance of nanoparticles to modulate crop responses at physiological, biochemical, metabolic, cellular, and molecular levels under abiotic stress conditions.- Role of metal and metal-oxide in agricultural crops salinity stress adaptation and mitigation.- Role of metal and metal-oxide in agricultural crops drought stress adaptation and mitigation.- Role of metal and metal-oxide in agricultural crops heavy metal stress adaptation and mitigation.- Role of metal and metal-oxide in agricultural crops mineral nutrient deficiency stress adaptation and mitigation.- Role of metal and metal-oxide in agricultural crops extreme temperatures stress adaptation and mitigation.- Role of metal and metal-oxide in agricultural crops flooding stress adaptation and mitigation.- Role of metal and metal-oxide in agricultural crops Ultraviolet (UV) radiation stress adaptation and mitigation.- Nanoparticles crosstalk or interaction with phytohormones for agricultural crops flooding stress adaptation and mitigation.- Nanoparticles crosstalk or interaction with gasotransmitters or signaling molecules for agricultural crops flooding stress adaptation and mitigation.- Nanoparticles crosstalk or interaction with beneficial microorganisms for agricultural crops flooding stress adaptation and mitigation.- Comparative evolution of the crop performance due to exposure of chemically and green synthesized nanoparticles under abiotic stress situation.- Interaction of arbuscular mycorrhizal fungi and nanoparticles in a soil matrix for enhanced plant growth and production under abiotic stress situation.- Changes in crop plants gene expression in response to nanoparticles exposure under abiotic stress situation.- Crop plants proteomic study on the effects of nanoparticles exposure under abiotic stress situation.- Specific physiological and molecular response of nanoparticles exposure to crop plants.- Long-term effects nanoparticles, safety concerns and optimal application methods of NPs in agricultural crops.
