Carboxylation reactions for the sustainable manufacture of chemicals and monomers

Laura Faba and Salvador Ordóñez
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Abstract

Carboxylation stands out as one of the most versatile and viable routes for carbon dioxide fixation, a crucial chemical transformation essential for advancing capture technologies and fostering a sustainable industry. The carboxylic acids and derivatives produced through this process hold considerable interest for various sectors, including pharmaceuticals and polymers. Presently, most of these chemicals are derived from non-renewable resources, underscoring the imperative need to develop sustainable pathways for their synthesis. The inherent stability of the CO2 molecule, owing to its high oxidation state and linear configuration, poses significant challenges for activation. Diverse approaches, including photochemical, electrochemical, enzymatic, and thermochemical carboxylation have been explored. While noteworthy results have been achieved with these methods, substantial efforts are still required to facilitate their scalability. This review provides a comprehensive overview of each of these routes, elucidating their respective strengths and weaknesses. Emphasis is placed on thermochemical routes, given their proximity to potential industrial-scale application.

Abstract Image

可持续生产化学品和单体的羧化反应
羧化是固定二氧化碳的最通用、最可行的途径之一,也是推进捕获技术和促进可持续发展工业所必需的重要化学转化。通过这一工艺生产的羧酸及其衍生物在制药和聚合物等各个领域都具有相当大的吸引力。目前,这些化学物质大多来自不可再生资源,因此迫切需要开发可持续的合成途径。由于二氧化碳分子的高氧化态和线性构型,其固有的稳定性给活化带来了巨大挑战。人们探索了多种方法,包括光化学、电化学、酶和热化学羧化。虽然这些方法已经取得了显著的成果,但仍需做出大量努力以促进其可扩展性。本综述全面概述了上述每种途径,阐明了它们各自的优缺点。重点放在热化学路线上,因为它们接近潜在的工业规模应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
0.60
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