Abstract

G. Malathi¹, C. Thillaiyadi Valliammai^1*, Rahul Ratnakar Mahamuni², Anthati Sreenivasulu³, J. Madhusudhanan⁴ and M.I. Niyas Ahamed⁵

DOI : http://dx.doi.org/10.13005/ojc/380511

Electricity is being used more directly and artificially than before. Working in a lab with a stronger synthetic emphasis enables the deployment of fresh ideas as well as ones that have been revived from earlier attempts in a wider range of situations. The amount of waste is decreased by using only electrons as reagents. Regenerating stoichiometric reagents in the correct molecular ratio can help electro catalytic catalysis. While minimizing waste is important, doing so also results in quicker and easier processes, gentler transitions, and the availability of more options, such as structural entities and IP space. Regenerative electricity can be used to give a terminal oxidizer or reducing agent that is extremely sustainable, which makes it a very alluring technology. Future electricity will be variable and plentiful, which will be very advantageous for value-added chemicals. The efficient conversion of renewable bio-based feedstocks serves as the first example of how contemporary electro-organic technologies can replace complex conventional processes. A new wave of sustainable chemistry will emerge if these obstacles are removed. This article takes a look at some recent developments in electrochemical synthesis that will undoubtedly affect how the discipline develops in the future.

Bio-based feedstocks; Electro catalytic; Electro-organic; Footprint; Electro-organic technologies; Stochastic

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