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Deciphering the Mass Transfer and Diffusion Behavior in the Oxidation of Fatty Alcohols to Fatty Acids over Pt/MCM-41
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  • Jiarong Lu,
  • Guoliang Li,
  • Yue Pan,
  • Mingyue Zhao,
  • Rong Fan,
  • Yihang Liu,
  • Zhibo Zhang,
  • Hui Zhao,
  • Xin Zhou,
  • Yibin Liu,
  • Xiaobo Chen,
  • Hao Yan,
  • Chaohe Yang
Jiarong Lu
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Guoliang Li
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Yue Pan
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Mingyue Zhao
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Rong Fan
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Yihang Liu
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Zhibo Zhang
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Hui Zhao
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Xin Zhou
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Yibin Liu
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Xiaobo Chen
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Hao Yan
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing

Corresponding Author:haoyan@upc.edu.cn

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Chaohe Yang
China University of Petroleum East China State Key Laboratory of Heavy Oil Processing
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Abstract

not-yet-known not-yet-known not-yet-known unknown Selective oxidation of long-chain fatty alcohols into acids is an important value-added reaction. However, exploring the basic catalytic steps over Pt-based catalysts throughout the entire oxidation process is still ambiguous. In this work, we systematically investigated the synergistic mechanisms of adsorption, reaction, and diffusion over Pt/MCM-41 for normal/isomeric alcohols oxidation into acids via molecular dynamics, in-situ characterization, and experiments. Specifically, diffusion coefficients decrease with the increase of the molecular weight of normal molecules due to the increased van der Waals forces, while isomeric alcohols exhibit more complex patterns originated from the steric hindrance between Pt particles and mesopores. To quantitatively describe this pattern, a cluster size descriptor of d Pt 0 . 75 × d Pore 0 . 25 was defined. Notably, 2-ethylhexanol exhibits the best self-diffusion coefficients at the descriptor value of 3.14. Correspondingly, the oxidation of 2-ethylhexanol to 2-ethylhexanoic acid displays highest reaction conversion (68.67%) and selectivity (65.59%).