<p>Direct conversion of CH<sub>4</sub> into liquid oxygenates under mild conditions is of great significance but remains challenging due to the high dissociation energy of inert C-H bond. Here we report the fabrication of a dual atomic Fe and Pd catalyst with periodic macroporous structure (Fe<sub>1</sub>-Pd<sub>1</sub> OMNC) toward the direct CH<sub>4</sub> conversion at room temperature. Mechanism studies reveal that a charge polarization region (O<sup>δ−</sup>-Fe-Pd<sup>δ+</sup>) is formed in-situ on Fe-Pd atomic sites upon oxidant activation, wherein the electron-rich O<sup>δ⁻</sup> and electron-deficient Pd<sup>δ+</sup> regions can respectively capture the H<sup>δ⁺</sup> and CH<sub>3</sub><sup>δ⁻</sup> in CH<sub>4</sub> and lead to the activation of C-H bond. As a result, Fe<sub>1</sub>-Pd<sub>1</sub> OMNC demonstrates attractive photothermal catalytic performance toward the selective oxidation of CH<sub>4</sub> under Xe lamp irradiation, achieving the productivities of C1 oxygenates as high as 0.754 mmol h<sup>−1</sup> and 0.035 mmol h<sup>−1</sup> when using H<sub>2</sub>O<sub>2</sub> or O<sub>2</sub> as the oxidant, respectively.</p>

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Formation of charge-polarized regions at dual single-atom sites for C-H bond activation in methane

  • Datong Chen,
  • Jingyi Zhou,
  • Wenyuan Lyu,
  • Xin Zhao,
  • Ruiqi Fang,
  • Fengliang Wang,
  • Yingwei Li

摘要

Direct conversion of CH4 into liquid oxygenates under mild conditions is of great significance but remains challenging due to the high dissociation energy of inert C-H bond. Here we report the fabrication of a dual atomic Fe and Pd catalyst with periodic macroporous structure (Fe1-Pd1 OMNC) toward the direct CH4 conversion at room temperature. Mechanism studies reveal that a charge polarization region (Oδ−-Fe-Pdδ+) is formed in-situ on Fe-Pd atomic sites upon oxidant activation, wherein the electron-rich Oδ⁻ and electron-deficient Pdδ+ regions can respectively capture the Hδ⁺ and CH3δ⁻ in CH4 and lead to the activation of C-H bond. As a result, Fe1-Pd1 OMNC demonstrates attractive photothermal catalytic performance toward the selective oxidation of CH4 under Xe lamp irradiation, achieving the productivities of C1 oxygenates as high as 0.754 mmol h−1 and 0.035 mmol h−1 when using H2O2 or O2 as the oxidant, respectively.