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Concerted oxygen diffusion across heterogeneous oxide interfaces for intensified propane dehydrogenation

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  • Sai Chen

    (Tianjin University
    Collaborative Innovation Center for Chemical Science & Engineering (Tianjin)
    International Campus of Tianjin University, Binhai New City)

  • Ran Luo

    (Tianjin University
    Collaborative Innovation Center for Chemical Science & Engineering (Tianjin)
    International Campus of Tianjin University, Binhai New City)

  • Zhi-Jian Zhao

    (Tianjin University
    Collaborative Innovation Center for Chemical Science & Engineering (Tianjin))

  • Chunlei Pei

    (Tianjin University
    Collaborative Innovation Center for Chemical Science & Engineering (Tianjin))

  • Yiyi Xu

    (Tianjin University
    Collaborative Innovation Center for Chemical Science & Engineering (Tianjin))

  • Zhenpu Lu

    (Tianjin University
    Collaborative Innovation Center for Chemical Science & Engineering (Tianjin))

  • Chengjie Zhao

    (Tianjin University
    Collaborative Innovation Center for Chemical Science & Engineering (Tianjin))

  • Hongbo Song

    (Tianjin University
    Collaborative Innovation Center for Chemical Science & Engineering (Tianjin))

  • Jinlong Gong

    (Tianjin University
    Collaborative Innovation Center for Chemical Science & Engineering (Tianjin)
    International Campus of Tianjin University, Binhai New City
    National Industry-Education Platform of Energy Storage)

Abstract

Propane dehydrogenation (PDH) is an industrial technology for direct propylene production which has received extensive attention in recent years. Nevertheless, existing non-oxidative dehydrogenation technologies still suffer from the thermodynamic equilibrium limitations and severe coking. Here, we develop the intensified propane dehydrogenation to propylene by the chemical looping engineering on nanoscale core-shell redox catalysts. The core-shell redox catalyst combines dehydrogenation catalyst and solid oxygen carrier at one particle, preferably compose of two to three atomic layer-type vanadia coating ceria nanodomains. The highest 93.5% propylene selectivity is obtained, sustaining 43.6% propylene yield under 300 long-term dehydrogenation-oxidation cycles, which outperforms an analog of industrially relevant K-CrOx/Al2O3 catalysts and exhibits 45% energy savings in the scale-up of chemical looping scheme. Combining in situ spectroscopies, kinetics, and theoretical calculation, an intrinsically dynamic lattice oxygen “donator-acceptor” process is proposed that O2- generated from the ceria oxygen carrier is boosted to diffuse and transfer to vanadia dehydrogenation sites via a concerted hopping pathway at the interface, stabilizing surface vanadia with moderate oxygen coverage at pseudo steady state for selective dehydrogenation without significant overoxidation or cracking.

Suggested Citation

  • Sai Chen & Ran Luo & Zhi-Jian Zhao & Chunlei Pei & Yiyi Xu & Zhenpu Lu & Chengjie Zhao & Hongbo Song & Jinlong Gong, 2023. "Concerted oxygen diffusion across heterogeneous oxide interfaces for intensified propane dehydrogenation," Nature Communications, Nature, vol. 14(1), pages 1-11, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-38284-0
    DOI: 10.1038/s41467-023-38284-0
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    References listed on IDEAS

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