Shape-Dependent CO 2 Hydrogenation to Methanol over Cu 2 O Nanocubes Supported on ZnO.
David KordusJelena JelicMauricio Lopez LunaNúria J DivinsJanis TimoshenkoSee Wee CheeClara RettenmaierJutta KröhnertStefanie KühlAnnette TrunschkeRobert SchlöglFelix StudtBeatriz Roldan CuenyaPublished in: Journal of the American Chemical Society (2023)
The hydrogenation of CO 2 to methanol over Cu/ZnO-based catalysts is highly sensitive to the surface composition and catalyst structure. Thus, its optimization requires a deep understanding of the influence of the pre-catalyst structure on its evolution under realistic reaction conditions, including the formation and stabilization of the most active sites. Here, the role of the pre-catalyst shape (cubic vs spherical) in the activity and selectivity of ZnO-supported Cu nanoparticles was investigated during methanol synthesis. A combination of ex situ , in situ , and operando microscopy, spectroscopy, and diffraction methods revealed drastic changes in the morphology and composition of the shaped pre-catalysts under reaction conditions. In particular, the rounding of the cubes and partial loss of the (100) facets were observed, although such motifs remained in smaller domains. Nonetheless, the initial pre-catalyst structure was found to strongly affect its subsequent transformation in the course of the CO 2 hydrogenation reaction and activity/selectivity trends. In particular, the cubic Cu particles displayed an increased activity for methanol production, although at the cost of a slightly reduced selectivity when compared to similarly sized spherical particles. These findings were rationalized with the help of density functional theory calculations.
Keyphrases
- metal organic framework
- room temperature
- carbon dioxide
- reduced graphene oxide
- density functional theory
- highly efficient
- visible light
- ionic liquid
- molecular dynamics
- high resolution
- quantum dots
- aqueous solution
- single molecule
- gold nanoparticles
- molecular dynamics simulations
- high throughput
- high speed
- simultaneous determination
- fluorescent probe