Recent Advances and Challenges in Electrocatalytic Carboxylation of CO2

IF 2 Q2 CHEMISTRY, ORGANIC

SynOpen Pub Date : 2024-04-22 DOI:10.1055/s-0043-1763748

Jie Wang, Zhen-Feng Wei, Yun-Xia Luo, Chang-Hai Lu, Ren-Jie Song

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Abstract

The electrochemical fixation of carbon dioxide onto organic matter has emerged as a promising approach in recent years. By combining the unique features of electrochemistry with the goal of carbon dioxide fixation, researchers aim to develop new strategies that can contribute to a more sustainable and environmentally friendly synthesis of organic compounds. One advantage of electrochemical methods is their ability to provide both electrons and energy for chemical transformations. This allows for the direct conversion of carbon dioxide into valuable organic products, without the need for transition metal catalysts or harsh reaction conditions. As a result, electrochemical carbon dioxide fixation offers the potential for milder and more efficient processes compared to traditional methods. Scientists have made noteworthy progress in exploring different strategies for the fixation of carbon dioxide under electrochemical conditions. These strategies involve the activation of various types of chemical bonds, including C(sp²)–C(sp²), C(sp²)–H, C–X (X = halogen), and C(sp³)–X (X = S, C, O, N). This review aims to provide an overview of the current state of research on electrochemical carbon dioxide fixation into organic matter. It will discuss the different strategies employed, the key findings, and the challenges that remain to be addressed. By highlighting the recent advancements in this field, this review hopes to inspire further exploration and innovation in the area of electrochemical synthesis for carbon dioxide fixation.

1 Introduction

2 Electrocatalytic Monocarboxylation of CO₂

2.1 Monocarboxylation of C(sp²)–C(sp²)

2.2 Monocarboxylation of C(sp²)–H

2.3 Monocarboxylation of C–X (X = Cl, Br, I)

2.4 Monocarboxylation of C(sp³)–X (X = S, C, O, N)

3 Electrocatalytic Dicarboxylation of CO₂

4 Electrocatalytic Esterification of CO₂

5 Conclusions

Abstract Image

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二氧化碳电催化羧化的最新进展和挑战

近年来，通过电化学方法将二氧化碳固定在有机物上已成为一种前景广阔的方法。通过将电化学的独特功能与二氧化碳固定的目标相结合，研究人员旨在开发出新的策略，从而有助于更可持续、更环保地合成有机化合物。电化学方法的一个优势是能够为化学转化提供电子和能量。这使得二氧化碳可以直接转化为有价值的有机产品，而无需过渡金属催化剂或苛刻的反应条件。因此，与传统方法相比，电化学二氧化碳固定法具有更温和、更高效的潜力。科学家们在探索电化学条件下固定二氧化碳的不同策略方面取得了显著进展。这些策略涉及激活各种类型的化学键，包括 C(sp2)-C(sp2)、C(sp2)-H、C-X（X = 卤素）和 C(sp3)-X（X = S、C、O、N）。本综述旨在概述电化学将二氧化碳固定到有机物中的研究现状。它将讨论所采用的不同策略、主要发现以及有待解决的挑战。通过重点介绍该领域的最新进展，本综述希望能激励人们在电化学合成固定二氧化碳领域进行进一步的探索和创新。1 引言 2 二氧化碳的电催化一羧化 2.1 C（sp2）-C（sp2）的一羧化 2.2 C（sp2）-H 的一羧化 2.3 C-X （X = Cl、Br、I）的一羧化 2.4 C（sp3）-X （X = S、C、O、N）的一羧化 3 二氧化碳的电催化二羧化 4 二氧化碳的电催化酯化 5 结论

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来源期刊

SynOpen CHEMISTRY, ORGANIC-

CiteScore

2.30

自引率

4.00%

发文量

审稿时长

6 weeks