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Insight into catalytic cracking pathways of n-pentane over bifunctional catalysts to produce light olefins
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  • Xinyang Zhang,
  • Yue Li,
  • Jiarong Lu,
  • Yuhang Hu,
  • Junfeng Chen,
  • Delun Ren,
  • Ze Li,
  • Qingchao Zhang,
  • Hao Yan,
  • Xiaobo Chen,
  • Yibin Liu,
  • Chaohe Yang
Xinyang Zhang
China University of Petroleum Huadong - Qingdao Campus
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Yue Li
China University of Petroleum Huadong - Qingdao Campus
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Jiarong Lu
China University of Petroleum Huadong - Qingdao Campus
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Yuhang Hu
China University of Petroleum Huadong - Qingdao Campus
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Junfeng Chen
China University of Petroleum Huadong - Qingdao Campus
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Delun Ren
China University of Petroleum Huadong - Qingdao Campus
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Ze Li
China University of Petroleum Huadong - Qingdao Campus
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Qingchao Zhang
China University of Petroleum Huadong - Qingdao Campus
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Hao Yan
China University of Petroleum Huadong - Qingdao Campus

Corresponding Author:haoyan@upc.edu.cn

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Xiaobo Chen
China University of Petroleum Huadong - Qingdao Campus
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Yibin Liu
China University of Petroleum Huadong - Qingdao Campus
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Chaohe Yang
China University of Petroleum Huadong - Qingdao Campus
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Abstract

Herein, we systematically investigated the reaction mechanism of n-pentane cracking on the Ag/ZSM-5 bifunctional catalyst featuring both dehydrogenation and cracking capabilities. Specifically, overall cracking network of n-pentane was comprehensively constructed to show the roles of metal dehydrogenation sites and acid sites respectively, in which metal Ag could substitute the H of the Brønsted acid site to form the Al-O-Ag linkage with enhanced adsorption and activation of n-pentane, while Brønsted acid site with weak acid strength relay to promote cracking reaction. Thanks to this synergy of the two active sites, the apparent activation energy of n-pentane cracking to light olefins was decreased from 82.77 KJ/mol to 68.26 KJ/mol and the proportion of specific path (C5H12→H2+C5H10) in n-pentane monomolecular cracking reaction increased from 14.62% to 69.24%. In addition, 0.57Ag/ZSM-5 catalyst exhibited the conversion of n-pentane up to 67.55wt%, which improved the performance of the parent ZSM-5 by 13.42wt%.