An investigation of the adsorption properties of water on binary AlSi clusters

The potential of doped aluminium clusters as catalysts for the water splitting reaction has attracted considerable scientific effort, however, the water-cluster interactions, which are a key step in the overall mechanism, are not fully understood. Here, we report an ab initio investigation of water adsorption on AlSi clusters at the MP2 level to elucidate the bonding and structural properties employing unary and binary 8- and 13-atom clusters, namely, Si 8 , Al 2 Si 6 , Al 4 Si 4 , Al 8 , Si 13 , Al 2 Si 11 , Al 12 Si, and Al 13 , which were selected by their relevance and energetic stability. We found that H 2 O binds via the O atom near to the on-top sites of the Si or Al atoms; in particular, there is a strong preference for the Al sites on the binary AlSi clusters, which is supported by the strong adsorption energy. Furthermore, we found a large enhancement of the adsorption energy on the Al 2 Si 6 and Al 2 Si 11 clusters, which can be explained by the cationic character of the Al site, which increases the Coulomb contribution to the Al + -O − interaction. Nanoalloys represent potential catalysts for the water splitting reaction. The water-cluster interaction is a key aspect of the process, but is not fully understood. This work provides an in-depth study and insights into the Al x Si y ·H 2 O case.