Alleviating inhibitory effect of H2 on low-temperature water-gas shift reaction activity of Pt/CeO2 catalyst by forming CeO2 nano-patches on Pt nano-particles

Pt/CeO 2 has gained much attention for their high activity in low-temperature (LT) water-gas shift (WGS) reaction. However, the inclusion of H 2 in the feed as in the practical reaction condition significantly degrades the LT-WGS activity of the Pt/CeO 2 catalysts. In this contribution, the activity of Pt/CeO 2 catalyst under the feed gas containing excess H 2 (20 vol% of H 2 ) was enhanced more than three times by forming CeO 2 nano-patches on Pt nano-particles. Both in-situ diffuse reflectance infrared Fourier transform spectroscopy and density functional theory calculation results indicate that dissociated H 2 on the Pt nano-particle inhibits the activity of the Pt/CeO 2 catalysts by occupying the active sites (Pt nano-particle-CeO 2 interface). On the other hand, thin CeO 2 nano-patches on Pt nano-particle suppressed the H 2 dissociation. As a result, the WGS reactivity of the active Pt nano-particle-CeO 2 interface was less affected by H 2 , granting the catalysts the high activity under the practical reaction conditions. • CO-FTIR band on Pt NP-CeO 2 interface is assigned, which appears at ~2090 cm −1 . • CeO 2 nano-patches are formed on Pt NPs by controlled reductive treatment. • The LT-WGS activity of Pt NP/CeO 2 is significantly inhibited by H 2 in the feed. • CeO 2 nano-patches inhibit the H 2 activation on Pt NP as confirmed by CO-FTIR. • CeO 2 nano-patches greatly enhance the LT-WGS activity under practical condition.