Nanoparticle-Based Catalysts for Sustainable Chemical Reactions: A Review of Recent Advances
DOI:
https://doi.org/10.36676/mdjc.v1.i2.7Keywords:
Nanoparticle-based catalysts, Sustainable chemical reactions, green chemistry, Catalytic efficiencyAbstract
Because of their high surface area, adjustable characteristics, and catalytic effectiveness, nanoparticle-based catalysts have emerged as an essential component in the advancement of environmentally friendly chemical reactions. These catalysts offer a variety of advantages that are not seen in other catalysts. There have been recent developments in the creation and application of nanoparticle catalysts in a variety of fields, such as green chemistry, environmental remediation, and energy production. Key areas of attention include the design and production of metal, metal oxide, and hybrid nanoparticles, as well as the functions that these nanoparticles play in improving selectivity, lowering energy consumption, and minimizing waste in catalytic processes. In addition, the paper draws attention to difficulties like as stability, recyclability, and the impact that nanoparticles have on the environment, while also proposing potential future paths for the optimization of catalytic systems. Through the enhancement of the efficiency of chemical transformations and the reduction of the environmental footprint of industrial processes, these innovations are poised to make a substantial contribution to the achievement of sustainability goals.
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