Your search keyword '"Deng, Yuchen"' showing total 3 results

1. Atomically dispersed Ir/α-MoC catalyst with high metal loading and thermal stability for water-promoted hydrogenation reaction.

Author

Li, Siwei, Cao, Ruochen, Xu, Mingquan, Deng, Yuchen, Lin, Lili, Yao, Siyu, Liang, Xuan, Peng, Mi, Gao, Zirui, Ge, Yuzhen, Liu, Jin-Xun, Li, Wei-Xue, Zhou, Wu, and Ma, Ding

Subjects

CATALYSTS, METAL catalysts, THERMAL stability, HYDROGENATION, HETEROGENEOUS catalysis, CATALYST supports

Abstract

Synthesis of atomically dispersed catalysts with high metal loading and thermal stability is challenging but particularly valuable for industrial application in heterogeneous catalysis. Here, we report a facile synthesis of a thermally stable atomically dispersed Ir/α-MoC catalyst with metal loading as high as 4 wt%, an unusually high value for carbide supported metal catalysts. The strong interaction between Ir and the α-MoC substrate enables high dispersion of Ir on the α-MoC surface, and modulates the electronic structure of the supported Ir species. Using quinoline hydrogenation as a model reaction, we demonstrate that this atomically dispersed Ir/α-MoC catalyst exhibits remarkable reactivity, selectivity and stability, for which the presence of high-density isolated Ir atoms is the key to achieving high metal-normalized activity and mass-specific activity. We also show that the water-promoted quinoline hydrogenation mechanism is preferred over the Ir/α-MoC, and contributes to high selectivity towards 1,2,3,4-tetrahydroquinoline. The present work demonstrates a new strategy in constructing a high-loading atomically dispersed catalyst for the hydrogenation reaction. [ABSTRACT FROM AUTHOR]

Published

2022

2. Tuning the Selectivity of Catalytic Carbon Dioxide Hydrogenation over Iridium/Cerium Oxide Catalysts with a Strong Metal-Support Interaction.

Author

Li, Siwei, Xu, Yao, Chen, Yifu, Li, Weizhen, Lin, Lili, Li, Mengzhu, Deng, Yuchen, Wang, Xiaoping, Ge, Binghui, Yang, Ce, Yao, Siyu, Xie, Jinglin, Li, Yongwang, Liu, Xi, and Ma, Ding

Subjects

IRIDIUM catalysts, CARBON dioxide, HYDROGENATION, CERIUM oxides, CATALYST supports

Abstract

A one-step ligand-free method based on an adsorption-precipitation process was developed to fabricate iridium/cerium oxide (Ir/CeO2) nanocatalysts. Ir species demonstrated a strong metal-support interaction (SMSI) with the CeO2 substrate. The chemical state of Ir could be finely tuned by altering the loading of the metal. In the carbon dioxide (CO2) hydrogenation reaction it was shown that the chemical state of Ir species-induced by a SMSI-has a major impact on the reaction selectivity. Direct evidence is provided indicating that a single-site catalyst is not a prerequisite for inhibition of methanation and sole production of carbon monoxide (CO) in CO2 hydrogenation. Instead, modulation of the chemical state of metal species by a strong metal-support interaction is more important for regulation of the observed selectivity (metallic Ir particles select for methane while partially oxidized Ir species select for CO production). The study provides insight into heterogeneous catalysts at nano, sub-nano, and atomic scales. [ABSTRACT FROM AUTHOR]

Published

2017

3. Anchoring Cu1 species over nanodiamond-graphene for semi-hydrogenation of acetylene.

Author

Huang, Fei, Deng, Yuchen, Chen, Yunlei, Cai, Xiangbin, Peng, Mi, Jia, Zhimin, Xie, Jinglin, Xiao, Dequan, Wen, Xiaodong, Wang, Ning, Jiang, Zheng, Liu, Hongyang, and Ma, Ding

Subjects

ETHYLENE, TRANSITION metal catalysts, ACETYLENE, OXIDATIVE dehydrogenation, HYDROGENATION, CATALYST supports

Abstract

The design of cheap, non-toxic, and earth-abundant transition metal catalysts for selective hydrogenation of alkynes remains a challenge in both industry and academia. Here, we report a new atomically dispersed copper (Cu) catalyst supported on a defective nanodiamond-graphene (ND@G), which exhibits excellent catalytic performance for the selective conversion of acetylene to ethylene, i.e., with high conversion (95%), high selectivity (98%), and good stability (for more than 60 h). The unique structural feature of the Cu atoms anchored over graphene through Cu-C bonds ensures the effective activation of acetylene and easy desorption of ethylene, which is the key for the outstanding activity and selectivity of the catalyst. It is highly desired to explore cheap, non-toxic transition metals catalysts for semihydrogenation of acetylene. Here, isolated Cu atoms anchored onto a defective nanodiamond-graphene support exhibit robust catalytic performance in acetylene semihydrogenation in comparison with supported Cu clusters. [ABSTRACT FROM AUTHOR]

Published

2019