电催化剂
法拉第效率
材料科学
甲醇
催化作用
异质结
选择性
化学工程
电化学
纳米技术
可再生能源
密度泛函理论
能量转换效率
碳纳米管
反应机理
能量转换
电流密度
协同催化
无机化学
作者
Xiangya Zhang,Mai Zhang,Min Xia,Zhen Zhang,Cong Luo,Yifei Yang,Li Zhang,Liangliang Wang,Jianjun Liao
标识
DOI:10.1002/adfm.202529725
摘要
ABSTRACT Electrochemical CO 2 reduction (CO 2 RR) to methanol offers a sustainable route for greenhouse gas mitigation and renewable energy storage, yet suffers from low selectivity due to competing pathways and intermediate instability. Herein, a BiOI/Co 9 S 8 heterojunction electrocatalyst was constructed, leveraging its unique nanotube architecture and the synergistic effect of the heterojunction to achieve highly efficient and selective CO 2 ‐to‐methanol conversion. In an H‐type cell, the catalyst exhibited a Faradaic efficiency of 68.29% for methanol at −0.9 V versus RHE and sustained stable operation for 60 h. In a flow cell, the methanol production rate reached 817.48 µmol h −1 cm −2 , with a partial current density of 122.57 mA cm −2 . Comparative experiments and calculations confirm that the synergistic interaction and interfacial confinement between BiOI and Co 9 S 8 lowers the energy barrier for the key intermediate HCOOH*, suppresses the formation of key intermediates such as *OCHO and *CO along the CO pathway, and thereby enables methanol production via the HCOOH pathway. This synergistic mechanism offers a novel strategy for the design of high‐performance CO 2 electroreduction catalysts for methanol synthesis.
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