脱氢
催化作用
甲醇
离解(化学)
铂金
制氢
化学
无机化学
水溶液
氢
材料科学
蒸汽重整
多相催化
光化学
羟基自由基
化学工程
激进的
氢原子
Atom(片上系统)
物理化学
金属
燃烧
作者
Hao Meng,Shaoteng Yuan,Zhiming Yin,Tianyao Shen,Kai Feng,Haisong Feng,Linlin Wang,Lirong Zheng,Song Hong,Yusen Yang,Jian Zhang,Xin Zhang,Min Wei
摘要
ABSTRACT Methanol aqueous reforming reaction (APRM) provides a green and clean route towards hydrogen production, in which the structure design and preparation of efficient catalysts remains a challenge. Herein, we report a platinum catalyst supported on the porous hydroxyl lanthanum oxide, which is prepared via glycine combustion method followed by a reduction process. The optimized 0.8%Pt/La catalyst, which is featured by Pt single‐atom dispersed on a La 2 (OH) 2 x O 3‐2 x support, exhibits an extraordinary catalytic performance towards APRM. A H 2 production rate of 7672 µmol H2 g cat −1 min −1 and an average turnover frequency (ATOF) of 11973 h ‒1 are obtained, which is preponderant to the state‐of‐the‐art catalysts. An in‐depth investigation based on kinetic isotope analysis, in situ spectroscopy characterizations and theoretical calculations substantiates that Pt single atom coordinated with adjacent lattice hydroxyl (OH L ) with electron transfer from Pt to support serves as the intrinsic active site, in which the Pt δ + site promotes the dehydrogenation of methoxyl whilst lattice hydroxyl directly participates in the oxidative coupling process (CH 2 O* + OH L → CH 2 OOH*). Furthermore, the Pt δ + −(OH L ) x −La interface sites can remarkably reduce the energy barrier of CH 2 OOH* dehydrogenation (rate‐determining step), and the resulting hydroxyl vacancies can boost H 2 O dissociation to recover consumed OH L , accounting for the exceptional catalytic performance.
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