Author
Listed:
- Shihui Zou
(Zhejiang University)
- Baohui Lou
(Zhejiang University)
- Kunran Yang
(ShanghaiTech University)
- Wentao Yuan
(Zhejiang University)
- Chongzhi Zhu
(Zhejiang University of Technology)
- Yihan Zhu
(Zhejiang University of Technology)
- Yonghua Du
(Institute of Chemical and Engineering Sciences, A*STAR
Brookhaven National Laboratory)
- Linfang Lu
(Zhejiang University)
- Juanjuan Liu
(Hangzhou Dianzi University)
- Weixin Huang
(University of Science and Technology of China)
- Bo Yang
(ShanghaiTech University)
- Zhongmiao Gong
(Chinese Academy of Sciences)
- Yi Cui
(Chinese Academy of Sciences)
- Yong Wang
(Zhejiang University)
- Lu Ma
(Brookhaven National Laboratory)
- Jingyuan Ma
(Shanghai Institute of Applied Physics Chinese Academy of Sciences)
- Zheng Jiang
(Shanghai Institute of Applied Physics Chinese Academy of Sciences)
- Liping Xiao
(Zhejiang University)
- Jie Fan
(Zhejiang University)
Abstract
Metal/oxide interface is of fundamental significance to heterogeneous catalysis because the seemingly “inert” oxide support can modulate the morphology, atomic and electronic structures of the metal catalyst through the interface. The interfacial effects are well studied over a bulk oxide support but remain elusive for nanometer-sized systems like clusters, arising from the challenges associated with chemical synthesis and structural elucidation of such hybrid clusters. We hereby demonstrate the essential catalytic roles of a nanometer metal/oxide interface constructed by a hybrid Pd/Bi2O3 cluster ensemble, which is fabricated by a facile stepwise photochemical method. The Pd/Bi2O3 cluster, of which the hybrid structure is elucidated by combined electron microscopy and microanalysis, features a small Pd-Pd coordination number and more importantly a Pd-Bi spatial correlation ascribed to the heterografting between Pd and Bi terminated Bi2O3 clusters. The intra-cluster electron transfer towards Pd across the as-formed nanometer metal/oxide interface significantly weakens the ethylene adsorption without compromising the hydrogen activation. As a result, a 91% selectivity of ethylene and 90% conversion of acetylene can be achieved in a front-end hydrogenation process with a temperature as low as 44 °C.
Suggested Citation
Shihui Zou & Baohui Lou & Kunran Yang & Wentao Yuan & Chongzhi Zhu & Yihan Zhu & Yonghua Du & Linfang Lu & Juanjuan Liu & Weixin Huang & Bo Yang & Zhongmiao Gong & Yi Cui & Yong Wang & Lu Ma & Jingyua, 2021.
"Grafting nanometer metal/oxide interface towards enhanced low-temperature acetylene semi-hydrogenation,"
Nature Communications, Nature, vol. 12(1), pages 1-11, December.
Handle:
RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-021-25984-8
DOI: 10.1038/s41467-021-25984-8
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Citations
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Cited by:
- Gunjan Sharma & Rishi Verma & Shinya Masuda & Khaled Mohamed Badawy & Nirpendra Singh & Tatsuya Tsukuda & Vivek Polshettiwar, 2024.
"Pt-doped Ru nanoparticles loaded on ‘black gold’ plasmonic nanoreactors as air stable reduction catalysts,"
Nature Communications, Nature, vol. 15(1), pages 1-16, December.
- Yao Zhang & Zezhou Li & Xing Tong & Zhiheng Xie & Siwei Huang & Yue-E Zhang & Hai-Bo Ke & Wei-Hua Wang & Jihan Zhou, 2024.
"Three-dimensional atomic insights into the metal-oxide interface in Zr-ZrO2 nanoparticles,"
Nature Communications, Nature, vol. 15(1), pages 1-10, December.
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