Evaluating the material capability of nickel vanadate NixV2Oy and rare earth gallium oxides RE3GaxOy RE Lu Nd nanostructures for applications in electrochemical super capacitors and hazardous agrochemical sensors

Abstract

The rapid depletion of fossil fuel reserves, alongside increasing newlineenvironmental pollution and global warming, has intensified the global newlinedemand for alternative energy technologies that emphasize higher efficiency newlineenergy storage devices. Addressing these challenges necessitates the newlinedevelopment of large-scale energy storage systems, which are crucial for newlineensuring energy reliability. Similarly, agricultural productivity plays a vital newlinerole in ensuring global food security and meeting the demands of a rapidly newlinegrowing population. Over the years, the introduction of agrochemicals, newlineincluding fertilizers, pesticides, herbicides, and fungicides, has significantly newlineenhanced the crop yields, provides improved pest management, and newlinerevolutionized modern agriculture. However, the widespread and often newlineindiscriminate use of agrochemicals raises concerns about their potential newlineimpact on human health and the environment. Additionally, the long-term newlinepersistence of certain agrochemicals in land and ecosystems has further newlineamplified these risks, necessitating a balance between maximizing newlineproductivity and safeguarding human and environmental health. The newlinedevelopment of stable, single-phase nanomaterials is crucial to addressing newlineenvironmental concerns. The research work emphasizes the role of transition newlinemetal oxide and rare gallium oxide families towards the exploration of newlineelectrochemical applications. newline