Unraveling CO adsorption on model single-atom catalysts.
Jan HulvaMatthias MeierRoland BliemZdeněk JakubFlorian KraushoferMichael SchmidUlrike DieboldCesare FranchiniGareth S ParkinsonPublished in: Science (New York, N.Y.) (2021)
Understanding how the local environment of a "single-atom" catalyst affects stability and reactivity remains a challenge. We present an in-depth study of copper1, silver1, gold1, nickel1, palladium1, platinum1, rhodium1, and iridium1 species on Fe3O4(001), a model support in which all metals occupy the same twofold-coordinated adsorption site upon deposition at room temperature. Surface science techniques revealed that CO adsorption strength at single metal sites differs from the respective metal surfaces and supported clusters. Charge transfer into the support modifies the d-states of the metal atom and the strength of the metal-CO bond. These effects could strengthen the bond (as for Ag1-CO) or weaken it (as for Ni1-CO), but CO-induced structural distortions reduce adsorption energies from those expected on the basis of electronic structure alone. The extent of the relaxations depends on the local geometry and could be predicted by analogy to coordination chemistry.
Keyphrases
- room temperature
- aqueous solution
- molecular dynamics
- highly efficient
- reduced graphene oxide
- ionic liquid
- metal organic framework
- electron transfer
- gold nanoparticles
- transition metal
- density functional theory
- high glucose
- optical coherence tomography
- diabetic rats
- oxidative stress
- quantum dots
- staphylococcus aureus
- health risk
- human health
- pseudomonas aeruginosa
- heavy metals
- biofilm formation
- oxide nanoparticles