Engineering nanointerfaces of Cu-based catalysts for balancing activity and stability of reverse water-gas-shift reaction

The strong metal support interaction (SMSI) is an important concept in heterogeneous catalysis and has been widely used to stabilize metal nanoparticles by inducing nanointerfaces between metal and support. Although many considerable signs of progress have been achieved in the SMSI establishment, the control of the nano -interfaces is barely studied, leading to inevitably sacrificed catalytic activity due to the excessive coverage. Herein, we investigated multiple strategies to effectively regulate nanointerfaces from different aspects, such as support composition, parameters of Cu preparation, pre-treatments and reaction conditions, to balance the ac-tivity and stability of Cu/TiO2 catalysts over reverse water-gas-shift (RWGS) reaction. It reveals that only Zn doping in TiO2 support can suppress the formation of nanointerfaces during reduction treatments due to the restraint of both TiO2 reducibility and electron transfer from TiO2 to Cu. The dynamic evolution of nano -interfaces is observed with the RWGS reaction conditions and finally reaches a stable state. The coverage of Cu that supported on the Zn-modified TiO2 significantly declined, resulting in a 44% increment in catalytic activity without sacrificing their stability at 700 degrees C. The proposed strategies on the nanointerfaces regulation can provide guidelines for balancing the activity and stability of catalysts from the aspects of catalyst design and conditions engineering.

Automated summary

The strong metal support interaction (SMSI) is a significant concept in heterogeneous catalysis, which stabilizes metal nanoparticles by inducing nanointerfaces between metal and support. This study investigates multiple strategies, including support composition, Cu preparation parameters, pre-treatments, and reaction conditions, to regulate nanointerfaces effectively and balance the activity and stability of Cu/TiO2 catalysts in the reverse water-gas-shift (RWGS) reaction.