电解水
材料科学
电解
催化作用
化学工程
烟气
碳酸盐
碳酸钙
合成气
膜
烟道
分子
分解水
无机化学
工作(物理)
电极
制氢
金属
碳纤维
光谱学
钙
氢
水泥
水蒸气
纳米技术
水处理
多相催化
电流(流体)
作者
Yuan Zhong,Yu Cui,Junbo Zhang,X. Wang,Xuecheng Guo,Qianqi Shi,Canyu Hu,Kun Zhou,Mingjun Shao,Wenqi Nie,Linhua Chu,Ning Zhang,Wenqing Zhang,Hengjie Liu,Ran Long,Ying Xiong
标识
DOI:10.1002/adma.202519757
摘要
ABSTRACT The performance of scalable, catholyte‐free membrane electrode assemblies (MEAs) is restricted by insufficient interfacial water and proton supply. Here, we present a general strategy for constructing an ideal proton‐feeding microenvironment based on calcium carbonate (CaCO 3 ), an earth‐abundant mineral. Using in situ spectroscopy and theoretical simulations, we reveal that the uniquely hydrophilic surface of CaCO 3 selectively enriches and stabilizes the more mobile and reactive liquid‐like water molecules (2‐HB·H 2 O), thereby establishing an efficient proton highway near the electrode. This enables metal‐loaded CaCO 3 (M/CaCO 3 , M = Zn, and Cu) catalysts to achieve exceptional performance at industrial‐relevant current densities. Crucially, we demonstrate that the catalyst can be synthesized on a kilogram scale directly from unpurified cement plant flue gas. This catalyst enables high‐rate CO 2 conversion to C 2+ (FE C2+ 77.97%) or syngas (19 L h − 1 ; the CO/H 2 ratio ∼2) in a 100 cm 2 electrolyzer stack. This work establishes a general paradigm for using natural minerals to manipulate interfacial water dynamics for industrial electrocatalysis.
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