4.6 Article

A carbon-efficient bicarbonate electrolyzer

Journal

CELL REPORTS PHYSICAL SCIENCE
Volume 4, Issue 11, Pages -

Publisher

CELL PRESS
DOI: 10.1016/j.xcrp.2023.101662

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Carbon efficiency is a pressing issue in the electroreduction of carbon dioxide. Existing electrolyzer systems suffer from low carbon efficiency. This study identifies the root causes of low carbon efficiency and proposes a solution using a near-neutral-pH cation exchange membrane, a glass fiber intermediate layer, and carbon dioxide partial pressure management. The proposed system achieves a carbon efficiency of over 96% by converting concentrated bicarbonate solution into solid formate fuel.
Carbon efficiency is one of the most pressing problems of carbon dioxide electroreduction today. While there have been studies on anion exchange membrane electrolyzers with carbon dioxide (gas) and bipolar membrane electrolyzers with bicarbonate (aqueous) feedstocks, both suffer from low carbon efficiency. In anion exchange membrane electrolyzers, this is due to carbonate anion crossover, whereas in bipolar membrane electrolyzers, the exsolution of carbon dioxide (gas) from the bicarbonate solution is the culprit. Here, we first elucidate the root cause of the low carbon efficiency of liquid bicarbonate electrolyzers with thermodynamic calculations and then achieve carbon-efficient carbon dioxide electroreduction by adopting a near-neutral-pH cation exchange membrane, a glass fiber intermediate layer, and carbon dioxide (gas) partial pressure management. We convert highly concentrated bicarbonate solution to solid formate fuel with a yield (carbon efficiency) of greater than 96%. A device test is demonstrated at 100 mA cm -2 with a full-cell voltage of 3.1 V for over 200 h.

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