Se-Incorporation Stabilizes and Activates Metastable MoS2 for Efficient and Cost-Effective Water Gas Shift Reaction

Although the water gas shift (WGS) reaction has sparked intensive attention for the production of high-purity hydrogen, the design of cost-efficient catalysts with noble metal-like performance still remains a great challenge. Here, we successfully overcome this obstacle by using Se-incorporated MoS2...

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Bibliographic Details
Published in:ACS nano 2019-10, Vol.13 (10), p.11303-11309
Main Authors: Zhu, Ting, Liu, Cheng, Tan, Xinyue, Huang, Bin, Bian, Guo-Qing, Shao, Qi, Bai, Shuxing, Qian, Yong, Li, Youyong, Huang, Xiaoqing
Format: Article
Language:English
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Summary:Although the water gas shift (WGS) reaction has sparked intensive attention for the production of high-purity hydrogen, the design of cost-efficient catalysts with noble metal-like performance still remains a great challenge. Here, we successfully overcome this obstacle by using Se-incorporated MoS2 with a 1T phase. Combining the optimized electronic structure, additional active sites from edge sites, and a sulfur vacancy based on the 1T phase, as well as the high surface ratio from the highly open structure, the optimal MoS1.75Se0.25 exhibits superior activity and stability compared to the conventional 2H-phase MoS2, with poor activity, large sulfur loss, and rapid inactivation. The hydrogen production of MoS1.75Se0.25 is 942 μmol, which is 1.9 times higher than MoS2 (504 μmol) and 2.8 times higher than MoSe2 (337 μmol). Furthermore, due to the lattice stabilization via Se-incorporation, MoS1.75Se0.25 exhibited excellent long-term stability without obvious change in more than 10 reaction rounds. Our results demonstrate a pathway to design efficient and cost-efficient catalysts for WGS.
ISSN:1936-0851
1936-086X
DOI:10.1021/acsnano.9b04444