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Pure-water-fed, electrocatalytic CO2 reduction to ethylene beyond 1,000 h stability at 10 A

Xiaojie She, Ling-Ling Zhai, Yifei Wang, Pei Xiong, Molly Meng‐Jung Li, Tai‐Sing Wu, Man‐Chung Wong, Xuyun Guo, Zhihang Xu, Huaming Li, Hui Xu, Ye Zhu, Shik Chi Edman Tsang, Shu Ping Lau

2024Nature Energy237 citationsDOIOpen Access PDF

Abstract

Abstract Electrocatalytic CO 2 reduction at near-ambient temperatures requires a complex inventory of protons, hydroxyls, carbonate ions and alkali-metal ions at the cathode and anode to be managed, necessitating the use of ion-selective membranes to regulate pH. Anion-exchange membranes provide an alkaline environment, allowing CO 2 reduction at low cell voltages and suppression of hydrogen evolution while maintaining high conversion efficiencies. However, the local alkaline conditions and the presence of alkali cations lead to problematic carbonate formation and even precipitation. Here we report a pure-water-fed (alkali-cation-free) membrane–electrode–assembly system for CO 2 reduction to ethylene by integrating an anion-exchange membrane and a proton-exchange membrane at the cathode and anode side, respectively, under forward bias. This system effectively suppresses carbonate formation and prevents salt precipitation. A scaled-up electrolyser stack achieved over 1,000 h stability without CO 2 and electrolyte losses and with 50% Faradaic efficiency towards ethylene at a total current of 10 A.

Topics & Concepts

ElectrolyteAnodeInorganic chemistryAlkali metalEthylene carbonateFaraday efficiencyMembraneCathodeChemistryEthyleneIon exchangeCarbonateHydrogenElectrodeIonCatalysisOrganic chemistryBiochemistryPhysical chemistryCO2 Reduction Techniques and CatalystsAdvanced battery technologies researchAmmonia Synthesis and Nitrogen Reduction
Pure-water-fed, electrocatalytic CO2 reduction to ethylene beyond 1,000 h stability at 10 A | Litcius