Overcoming copper stability challenges in CO2 electrolysis

IF 79.8 1区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

Nature Reviews Materials Pub Date : 2025-06-16 DOI:10.1038/s41578-025-00815-0

Jesse Kok, Petru P. Albertini, Jari Leemans, Raffaella Buonsanti, Thomas Burdyny

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Abstract

Copper and copper-based catalysts can electrochemically convert CO₂ into ethylene and higher alcohols, among other products, at room temperature and pressure. This approach may be suitable for the production of high-value compounds. However, such a promising reaction is heavily burdened by the instability of copper during CO₂ reduction. To date, non-copper catalysts have also failed to supplant the activity and selectivity of copper, leaving CO₂-to-C₂ electrolysis in the balance. In this Perspective, we discuss copper catalyst instability from both the atomistic and the microstructure viewpoint. We motivate that increased fundamental understanding, material design and operational approaches, along with increased reporting of failure mechanisms, will contribute to overcoming the barriers to multi-year operation. Our narrative focuses on the copper catalyst reconstruction occurring during CO₂ reduction as one of the major causes inducing loss of C₂ activity. We conclude with a rational path forward towards longer operations of CO₂-to-C₂ electrolysis.

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克服CO2电解中铜稳定性的挑战

铜和铜基催化剂可以在室温和常压下电化学地将二氧化碳转化为乙烯和高级醇，以及其他产品。这种方法可能适用于高价值化合物的生产。然而，这样一个有希望的反应是沉重的负担铜在CO2还原过程中的不稳定性。迄今为止，非铜催化剂也未能取代铜的活性和选择性，使二氧化碳到c2的电解处于平衡状态。本文从原子和微观两方面讨论了铜催化剂的不稳定性。我们认为，增加对基础知识的理解、材料设计和操作方法，以及增加对故障机制的报告，将有助于克服多年运行的障碍。我们的叙述重点是铜催化剂的重建发生在CO2还原过程中，这是导致C2活性损失的主要原因之一。最后，我们提出了一条合理的途径，以实现更长时间的二氧化碳- c2电解操作。

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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来源期刊

Nature Reviews Materials Materials Science-Biomaterials

CiteScore

119.40

自引率

0.40%

发文量

107

期刊介绍： Nature Reviews Materials is an online-only journal that is published weekly. It covers a wide range of scientific disciplines within materials science. The journal includes Reviews, Perspectives, and Comments. Nature Reviews Materials focuses on various aspects of materials science, including the making, measuring, modelling, and manufacturing of materials. It examines the entire process of materials science, from laboratory discovery to the development of functional devices.