Advanced Science (Jun 2018)

Tailoring Surface Frustrated Lewis Pairs of In2O3−x(OH)y for Gas‐Phase Heterogeneous Photocatalytic Reduction of CO2 by Isomorphous Substitution of In3+ with Bi3+

  • Yuchan Dong,
  • Kulbir Kaur Ghuman,
  • Radian Popescu,
  • Paul N. Duchesne,
  • Wenjie Zhou,
  • Joel Y. Y. Loh,
  • Feysal M. Ali,
  • Jia Jia,
  • Di Wang,
  • Xiaoke Mu,
  • Christian Kübel,
  • Lu Wang,
  • Le He,
  • Mireille Ghoussoub,
  • Qiang Wang,
  • Thomas E. Wood,
  • Laura M. Reyes,
  • Peng Zhang,
  • Nazir P. Kherani,
  • Chandra Veer Singh,
  • Geoffrey A. Ozin

DOI
https://doi.org/10.1002/advs.201700732
Journal volume & issue
Vol. 5, no. 6
pp. n/a – n/a

Abstract

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Abstract Frustrated Lewis pairs (FLPs) created by sterically hindered Lewis acids and Lewis bases have shown their capacity for capturing and reacting with a variety of small molecules, including H2 and CO2, and thereby creating a new strategy for CO2 reduction. Here, the photocatalytic CO2 reduction behavior of defect‐laden indium oxide (In2O3−x(OH)y) is greatly enhanced through isomorphous substitution of In3+ with Bi3+, providing fundamental insights into the catalytically active surface FLPs (i.e., InOH···In) and the experimentally observed “volcano” relationship between the CO production rate and Bi3+ substitution level. According to density functional theory calculations at the optimal Bi3+ substitution level, the 6s2 electron pair of Bi3+ hybridizes with the oxygen in the neighboring InOH Lewis base site, leading to mildly increased Lewis basicity without influencing the Lewis acidity of the nearby In Lewis acid site. Meanwhile, Bi3+ can act as an extra acid site, serving to maximize the heterolytic splitting of reactant H2, and results in a more hydridic hydride for more efficient CO2 reduction. This study demonstrates that isomorphous substitution can effectively optimize the reactivity of surface catalytic active sites in addition to influencing optoelectronic properties, affording a better understanding of the photocatalytic CO2 reduction mechanism.

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