Abstract
AbstractThe commercial high‐temperature water‐gas shift (HT‐WGS) catalyst consists of CuO‐Cr2O3‐Fe2O3, where Cu functions as a chemical promoter to increase the catalytic activity, but its promotion mechanism is poorly understood. In this work, a series of iron‐based model catalysts were investigated with in situ or pseudo in situ characterization, steady‐state WGS reaction, and density function theory (DFT) calculations. For the first time, a strong metal‐support interaction (SMSI) between Cu and FeOx was directly observed. During the WGS reaction, a thin FeOx overlayer migrates onto the metallic Cu particles, creating a hybrid surface structure with Cu‐FeOx interfaces. The synergistic interaction between Cu and FeOx not only stabilizes the Cu clusters, but also provides new catalytic active sites that facilitate CO adsorption, H2O dissociation, and WGS reaction. These new fundamental insights can potentially guide the rational design of improved iron‐based HT‐WGS catalysts.
Highlights
The commercial high temperature water-gas shift (HTWGS) catalyst consists of CuO-Cr2O3-Fe2O3, where Cu functions as a chemical promoter to increase the catalytic activity but its promotion mechanism is poorly understood
Example, Fu et al developed a new class of LT-WGS catalysts with Au or Pt supported on cerium oxide
Rodriguez et al demonstrated by investigating the inverse CeO2/Au and TiO2/Au model compounds that oxide-metal interface directly participated in the LT-WGS reaction
Summary
The commercial high temperature water-gas shift (HTWGS) catalyst consists of CuO-Cr2O3-Fe2O3, where Cu functions as a chemical promoter to increase the catalytic activity but its promotion mechanism is poorly understood. As the surface areas of both catalysts were comparable after the WGS reaction
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