在气体扩散电极和电解质中将电化学二氧化碳还原与基于膜/吸附的二氧化碳捕获相结合

EcoEnergy Pub Date : 2024-01-26 DOI:10.1002/ece2.23
Hesamoddin Rabiee, Penghui Yan, Hao Wang, Zhonghua Zhu, Lei Ge
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摘要

电化学二氧化碳还原反应(CO2RR)因其独特的优势,如在环境条件下运行、与可再生能源发电耦合、可生产多种产品和商品等,在过去十年中备受关注。大多数 CO2RR 研究都以纯 CO2 为原料,而在实际的 CO2 废弃物流(如烟道气或沼气)中,CO2 的浓度不超过 40%。因此,CO2RR 的经济可行性及其碳足迹在很大程度上受到电解前 CO2 净化步骤的限制(CO2/N2 分离每吨 CO2 70-100 美元)。近年来,通过将二氧化碳捕集和电还原整合到一个装置中,研究显示了这一问题的重要性。作为电解质的二氧化碳捕集溶液受到了广泛关注,并取得了可喜的成果,显著提高了 CO2RR 的整体经济性。对二氧化碳捕集-电还原一体化的关注可以超越基于溶液/电解质的二氧化碳捕集(如胺溶液和离子液体),其他工艺,如固体吸附和基于膜的工艺,作为更有效的选择,有可能在气体扩散电极设计中与二氧化碳电还原相结合。本文旨在回顾近年来在整合二氧化碳捕集与电还原方面所做的努力,并为基于膜和吸附的二氧化碳捕集与还原整合的材料选择和电极设计提供新的视角,此外还分析了这种整合的经济可行性。
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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Electrochemical CO2 reduction integrated with membrane/adsorption-based CO2 capture in gas-diffusion electrodes and electrolytes

Electrochemical CO2 reduction reaction (CO2RR) has attracted much attention in the last decade, owing to its unique advantages such as operation at ambient conditions, coupling with renewable electricity, and producing a wide range of products and commodities. The majority of CO2RR studies are focused on pure CO2 as feed, while in real CO2 waste streams, such as flue gas or biogas, CO2 concentration does not exceed 40%. Therefore, the economic feasibility of CO2RR and its carbon footprint are greatly limited by the CO2 purification steps before electrolysis ($70–100 per ton of CO2 for CO2/N2 separation). In recent years, studies have exhibited the importance of this matter by integrating CO2 capture and electroreduction in a single unit. Mostly, CO2 capture solutions as electrolytes have been under attention, and promising results have been achieved to significantly improve the overall economy of CO2RR. The focus on CO2 capture-electroreduction integration can go beyond the solution/electrolyte-based CO2 capture (e.g., amine solutions and ionic liquids) and other processes such as solid adsorption and membrane-based processes, as more efficient options, can be potentially integrated with CO2 electroreduction in the gas-diffusion electrode design. This article aims to review the recent efforts in integrating capture and electroreduction of CO2 and provides new perspectives in material selection and electrode design for membrane- and adsorption-based CO2 capture-reduction integration, in addition to the analysis of the economic feasibility of this integration.

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