Abstract
Single atom catalysts have been found to exhibit superior selectivity over nanoparticulate catalysts for catalytic reactions such as hydrogenation due to their single-site nature. However, improved selectively is often accompanied by loss of activity and slow kinetics. Here we demonstrate that neighboring Pd single atom catalysts retain the high selectivity merit of sparsely isolated single atom catalysts, while the cooperative interactions between neighboring atoms greatly enhance the activity for hydrogenation of carbon-halogen bonds. Experimental results and computational calculations suggest that neighboring Pd atoms work in synergy to lower the energy of key meta-stable reactions steps, i.e., initial water desorption and final hydrogenated product desorption. The placement of neighboring Pd atoms also contribute to nearly exclusive hydrogenation of carbon-chlorine bond without altering any other bonds in organohalogens. The promising hydrogenation performance achieved by neighboring single atoms sheds light on a new approach for manipulating the activity and selectivity of single atom catalysts that are increasingly studied in multiple applications.
Highlights
Single atom catalysts have been found to exhibit superior selectivity over nanoparticulate catalysts for catalytic reactions such as hydrogenation due to their single-site nature
Single atom catalysts (SACs) represent a rapidly emerging trend in catalyst design, where atomic dispersion ensures that each metal atom is exposed and available for catalytic reactions[1,2]
We demonstrate that a neighboring Pd SAC (n-Pd1) exhibits both high activity and selectivity for hydrodehalogenation catalysis, significantly surpassing both isolated Pd SAC (i-Pd1) and Pd nanoparticles (Pdnano)
Summary
Single atom catalysts have been found to exhibit superior selectivity over nanoparticulate catalysts for catalytic reactions such as hydrogenation due to their single-site nature. Energy-dispersive X-ray spectroscopy suggests successful loading of Pd atoms that are uniformly distributed across the SiC surface (Supplementary Fig. 1).
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