脱氢
催化作用
化学
氧气
乙醛
醋酸
选择性
离解(化学)
光化学
激进的
部分氧化
无机化学
氢
氧合物
密度泛函理论
产量(工程)
乙醇
分解
碳氢化合物
甲醛
合成气
过氧化氢
极限氧浓度
反应机理
多相催化
作者
Bin Li,Siquan Feng,Jiaqian Wang,Xinzhe Song,Guifa Long,Jiali Mu,Yue Zhang,Fangcen Liu,Ende Huang,Siyue Liu,Fanfei Sun,Wenrui Dong,Weiqing Zhang,Xueming Yang,Dehui Deng,Zhongkang Han,Li Yan,Yunjie Ding
标识
DOI:10.1002/anie.202521562
摘要
ABSTRACT The low‐temperature direct conversion of ethane is more appealing for the utilization of shale gas. Dual‐atom catalysts have attracted considerable attention due to their unique cooperative effects. Herein, we report a porous organic polymer‐supported Rh 1 –Cu 1 dual‐site catalyst (Rh 1 –Cu 1 @POPs‐PPh 3 ) for the selective oxidation of ethane to ethanol, acetaldehyde, and acetic acid with auto‐selective oxygen mechanism. The optimized Rh 1 –Cu 1 centers deliver a productivity of ca. 250 mol mol Rh −1 h −1 based on Rh with 65% acetaldehyde selectivity at 423 K, representing a four‐fold improvement over the single‐Rh‐site catalyst. Through isotopic labeling and in situ characterizations, we uncover an auto‐selective oxygen source mechanism in which dehydrogenated species of ethane with different grades possess self‐selectivity for the combined oxygen source. Oxygen species derived from O 2 activate ethane and subsequently couple with the ethyl fragment to produce ethanol. While OH radicals from H 2 O dissociation react with ethyl intermediates from ethane dehydrogenation to yield acetaldehyde. Concurrently, oxygen species recombine with reactive hydrogen species to regenerate new H 2 O, completing the catalytic oxidation cycle. The density functional theory (DFT) calculations reveal that the Rh–Cl–Cu configuration lowers the lowest unoccupied molecular orbital (LUMO) energy of Rh 1 , thereby strengthening adsorbate‐metal interactions, weakening the C─H bond, and facilitating its activation.
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