CO2 reforming with methane reaction over Ni@SiO2 catalysts coupled by size effect and metal-support interaction

[Display omitted] •Core-shell structured Ni@SiO2 catalysts with ultrafine Ni nanoparticles were fabricated.•Catalytic performance of DRM was from coupling of size effect and SMIS in the Ni@SiO2 catalysts.•The Ni@SiO2-600 catalyst had intermediate Ni size and SMIS achieved the best coupling. CO2 refo...

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Bibliographic Details
Published in:Fuel (Guildford) 2019-11, Vol.256, p.115954, Article 115954
Main Authors: Zhang, Linjia, Wang, Fagen, Zhu, Jiayin, Han, Bolin, Fan, Weiqiang, Zhao, Long, Cai, Weijie, Li, Zhongcheng, Xu, Leilei, Yu, Hao, Shi, Weidong
Format: Article
Language:English
Subjects:
Carbon dioxide
Catalysis
Catalysts
CO2 reforming with methane
Deposition
Emissions control
Greenhouse effect
Greenhouse gases
High temperature
Metal-support interaction
Metals
Methane
Nanoparticles
Ni@SiO2
Nickel
Reforming
Silicon dioxide
Size effect
Size effects
Synthesis gas
Ultrafines
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Summary:[Display omitted] •Core-shell structured Ni@SiO2 catalysts with ultrafine Ni nanoparticles were fabricated.•Catalytic performance of DRM was from coupling of size effect and SMIS in the Ni@SiO2 catalysts.•The Ni@SiO2-600 catalyst had intermediate Ni size and SMIS achieved the best coupling. CO2 reforming with methane is an attractive reaction to produce syngas and reduce greenhouse gases. The main problems for the reaction are catalyst sintering and carbon deposition at high temperatures. In this study, we fabricated core-shell structured Ni@SiO2 catalysts with ultrafine nickel nanoparticles by microemulsion method. The catalysts were calcined at different temperatures to obtain different sizes of Ni nanoparticles and achieve different strengths of metal-support interaction. CO2 reforming with methane reaction over the Ni@SiO2 catalysts revealed that catalytic performance was dependent on both size of Ni nanoparticles and strength of metal-support interaction. The best coupling of size effect and metal-support interaction in the Ni@SiO2-600 exhibited the highest performance and stability, which was assigned to the maintained smallest size of Ni nanoparticles and the lowest carbon deposition when compared with Ni@SiO2-500 and Ni@SiO2-700 catalysts.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2019.115954