Abstract
The physical and chemical properties of bimetallic nanoparticles can be optimized by tuning the particle composition. In this study, we identified CO adsorption and dissociation energetics on five Pt-Mo nanoparticles at different concentrations, the lowest energy Pt7, Pt6Mo, Pt5Mo2, Pt4Mo3, and Mo7 clusters. We have shown that the CO adsorption and dissociation energies and preferred CO adsorption sites are largely dependent on the composition of the nanoparticles. As the Mo concentration increases, the strength of the C-O internal bond in the adsorption complex decreases, as indicated by a decrease in the C-O stretching frequency. Also, more Mo sites in the nanoparticle become available for CO adsorption, and the preferred CO adsorption site switches from Pt to Mo. For these reasons, dissociation of CO is energetically favorable on Pt4Mo3 and Mo7. On both compositions, we have shown that the dissociation paths begin with CO adsorbed on a Mo site in a multifold configuration, in particular in a tilted configuration. These findings provide insight on the effects of the composition on the chemical and catalytical properties of Pt-Mo nanoparticles, thereby guiding future experiments on the synthesis of nanoparticles, especially those that may be suitable for various desired applications containing CO.
Highlights
Atomic and molecular nanoparticles and related systems and phenomena are subjects of a rapidly developing research field
A recent scanning tunneling microscopy study on small size Pt/TiO 2 clusters shows that the transformation from planar to 3-dimensional packing in Pt n nanoparticles occurs at size n = 8 atoms [51]
We found that the singlet state of Mo 7 is 0.015 eV higher in energy than the triplet state
Summary
Atomic and molecular nanoparticles and related systems and phenomena are subjects of a rapidly developing research field. The unique potential of nanoparticles to attain various thermal properties, electronic features, and chemical reactivity through changes in size, structure, and composition allows researchers to customize them according to desired application areas [6,7,8,9]. By tuning size, shape, and composition, it is possible to achieve high activity and selectivity in chemical transformations. One of these reactive systems where nanocatalysts find application is at the anodic side of low-temperature fuel cells [10]. Due to the formation of strong Pt-CO bonds, the active sites are blocked even in the presence of small amounts of CO in the fuel gas and the hydrogen dissociation performance of the catalyst degrades rapidly.
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