1. Engineering Three-Layer Core–Shell S-1/Ts-1@ Dendritic-Sio2 Supported Au Catalysts Towards Improved Performance for Propene Epoxidation with H2 and O2
- Author
-
Xin Jin, Zhaoning Song, Nan Sheng, Dong Lin, Zhenping Cai, Chaohe Yang, Juncong Yuan, Xiaobo Chen, Xiang Feng, Yibin Liu, and De Chen
- Subjects
Materials science ,lcsh:TJ807-830 ,Shell (structure) ,lcsh:Renewable energy sources ,02 engineering and technology ,010402 general chemistry ,01 natural sciences ,Catalysis ,Propene ,Propene epoxidation ,chemistry.chemical_compound ,Mass transfer ,TS-1 ,lcsh:QH540-549.5 ,Selectivity ,Core-shell ,Renewable Energy, Sustainability and the Environment ,021001 nanoscience & nanotechnology ,0104 chemical sciences ,Improved performance ,chemistry ,Chemical engineering ,Dendritic SiO2 shell ,lcsh:Ecology ,0210 nano-technology ,Mesoporous material ,Layer (electronics) - Abstract
The advocacy of green chemical industry has led to the development of highly efficient catalysts for direct gas-phase propene epoxidation with green, sustainable and simple essence. The S-1/TS-1@dendritic-SiO2 material with three-layer core–shell structure was developed and used as the support for Au catalysts, which showed simultaneously fantastic PO formation rate, PO selectivity and stability (over 100 h) for propene epoxidation with H2 and O2. It is found that silicalite-1 (S-1) core and the middle thin layer of TS-1 offer great mass transfer ability, which could be responsible for the excellent stability. The designed dendritic SiO2 shell covers part of the acid sites on the external surface of TS-1, inhibiting the side reactions and improving the PO selectivity. Furthermore, three kinds of SiO2 shell morphologies (i.e., dendritic, net, mesoporous shell) were designed, and relationship between shell morphology and catalytic performance was elucidated. The results in this paper harbour tremendous guiding significance for the design of highly efficient epoxidation catalysts.
- Published
- 2020