From Lab to Technical CO2 Hydrogenation Catalysts: Understanding PdZn Decomposition

Nano-alloy Catalysts for Methanol Synthesis from CO2 Hydrogenation

Nano-alloy catalysts (NACs), which differ appreciably from monometallic catalysts, take on superior intrinsic features in surface microstructure, surface electronic properties, homogeneity in nanoscale, etc., endowing them with attractive prospects in heterogeneous catalysis. In particular, methanol synthesis from CO2 exhibits high potentials in terms of alternative energy sources to fossil fuels and NACs have shown promising performance in promoting the reaction. However, there still lacks of the bottom-up catalysts design as well as the unanimous insight regarding the mechanistic understanding. Herein, we present a comprehensive overview of the physico-chemical properties and the fabrication approach to NACs with high catalytic performance in the CO2 hydrogenation to methanol. Additionally, the progresses of NACs were comprehensively summarized in terms of mechanisms. Finally, some thinking about the further relevant studies on NACs is outlooked with the aim to provide new insights for achieving the precise design and controllable properties of NACs.

Deciphering Local Structural Complexity in Zn/Ga-ZrO2 CO2 Hydrogenation Catalysts

In the last few decades, massive effort has been expended in heterogeneous catalysis to develop new materials presenting high conversion, selectivity, and stability even under high-temperature and high-pressure conditions. In this context, CO2 hydrogenation is an interesting reaction where the catalyst local structure is strongly related to the development of an active and stable material under hydrothermal conditions at T/P > 300 °C/30 bar. In order to clarify the relationship between catalyst local ordering and its activity/stability, we herein report a combined laboratory and synchrotron investigation of aliovalent element (Ce/Zn/Ga)-containing ZrO2 matrixes. The results reveal the influence of similar average structures with different short-range orderings on the catalyst properties. Moreover, a further step toward the comprehension of the oxygen vacancy formation mechanism in Ce- and Ga-ZrO2 catalysts is reported. Finally, the reported results illustrate a robust method to guide local structure determination and ultimately help to avoid overuse of the "solid solution" definition.

Zn Redistribution and Volatility in ZnZrOx Catalysts for CO2 Hydrogenation

ZnO-ZrO2 mixed oxide (ZnZrOx) catalysts are widely studied as selective catalysts for CO2 hydrogenation into methanol at high-temperature conditions (300-350 °C) that are preferred for the subsequent in situ zeolite-catalyzed conversion of methanol into hydrocarbons in a tandem process. Zn, a key ingredient of these mixed oxide catalysts, is known to volatilize from ZnO under high-temperature conditions, but little is known about Zn mobility and volatility in mixed oxides. Here, an array of ex situ and in situ characterization techniques (scanning electron microscopy/energy dispersive X-ray spectroscopy (SEM/EDX), transmission electron microscopy (TEM), powder X-ray diffraction (PXRD), X-ray absorption spectroscopy (XAS), X-ray photoelectron spectroscopy (XPS), Infrared (IR)) was used to reveal that Zn2+ species are mobile between the solid solution phase with ZrO2 and segregated and/or embedded ZnO clusters. Upon reductive heat treatments, partially reversible ZnO cluster growth was observed above 250 °C and eventual Zn evaporation above 550 °C. Extensive Zn evaporation leads to catalyst deactivation and methanol selectivity decline in CO2 hydrogenation. These findings extend the fundamental knowledge of Zn-containing mixed oxide catalysts and are highly relevant for the CO2-to-hydrocarbon process optimization.