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Journal of Materials Science

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05-02-2024 | Chemical routes to materials

Effect of ZnZrO_x nanocrystal size on catalytic performance in the production of light olefins from carbon dioxide

Authors: Qian Wang, Heping Zheng, Daqiang Xiao, Yu Ren, Jianhua Tang

Published in: Journal of Materials Science | Issue 6/2024

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Abstract

ZnZrO_x has been used in large quantities for the preparation of light olefins from CO₂, but the relationship between structure and performance remains unclear at present. In this paper, ZnZrO_x were prepared by co-precipitation method, and a series of oxides with different sizes were prepared by varying the calcination temperatures. Subsequently, these oxides were combined with SAPO-34 to create a composite bifunctional catalyst for the synthesis of light olefins by CO₂ hydrogenation, in which the impact of nanocrystal size effect was examined. The catalytic performance significantly increased as the nanocrystal size reduced from 18 to 12 nm. However, when the nanocrystal size was further decreased to 8 nm, the catalytic performance decline. Characterizations revealed a gradual increase in the number of oxygen vacancies with decreasing nanocrystal size. However, the oxide with the smallest nanocrystal size, prepared by varied calcination temperatures, did not yield the optimal catalytic performance due to sintering occurring during the reaction process. The results show that the assumption that smaller nanocrystal sizes inherently equate to improved catalytic performance is not universally valid, and stability must be considered when the nanocrystal size is decreased. The bifunctional catalysts used in this paper for the prepared light olefins from CO₂ in yield as high as 13.8%, which is higher than most previous reports.

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Title: Effect of ZnZrOx nanocrystal size on catalytic performance in the production of light olefins from carbon dioxide
Authors: Qian Wang
Heping Zheng
Daqiang Xiao
Yu Ren
Jianhua Tang
Publication date: 05-02-2024
Publisher: Springer US
Published in: Journal of Materials Science / Issue 6/2024
Print ISSN: 0022-2461
Electronic ISSN: 1573-4803
DOI: https://doi.org/10.1007/s10853-024-09354-5

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