催化作用
光催化
材料科学
选择性
丙烷
联轴节(管道)
碳纤维
对偶(语法数字)
还原(数学)
光化学
动力学
化学工程
法拉第效率
链条(单位)
碳链
化学稳定性
化学
反应中间体
活动站点
无机化学
科技与社会
纳米技术
电子转移
作者
Yan Wu,Jiaxin Jiang,Qingqing Chen,Chengyang Zhu,Dongyang Yu,Ning Lü,Junjie Mao
标识
DOI:10.1002/anie.202521193
摘要
Abstract The photocatalytic conversion of CO 2 and H 2 O into long carbon chain products (C n , n ≥ 3) presents a sustainable strategy for synthesizing high‐value fuels and chemicals. However, the synthesis of long carbon chain products under mild conditions still faces great challenges, largely due to sluggish multi‐electron/proton transfer kinetics and the thermodynamically unfavorable C 1 –C 1 and C 1 –C 2 coupling processes. In this study, we developed tri‐metal active sites composed of Ni single atoms and Mn 2 dual atoms anchored on NH 2 ‐MIL‐125(Ti) (Ni 1 /Mn 2 ‐MIL) for synergistic photocatalytic C 3 H 8 production. The synthesized Ni 1 /Mn 2 ‐MIL catalyst achieved efficient CO 2 photoreduction (CO 2 PR) in pure water, yielding 32.2 µmol g −1 h −1 of C 3 H 8 with 81.3% electron‐based selectivity, significantly outperforming Ni 1 ‐MIL and Mn 2 ‐MIL. Remarkably, the catalyst exhibited exceptional stability over 50 cycles without degradation. Integrated experimental and theoretical investigations revealed that the Ni 1 site activates CO 2 to form CO, while the adjacent Mn 2 site promotes the formation of *COCHO intermediates. Strong electronic interactions between Ni 1 and Mn 2 create charge‐polarized active sites, which mitigate electrostatic repulsion between C 1 and C 2 intermediates, thereby promoting C–C coupling and subsequent formation of the *CH 2 OCOCO intermediates. Consequently, both the selectivity and catalytic efficiency toward C 3 H 8 production are significantly enhanced.
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