Under an industry-related high-temperature
oxidation atmosphere,
the structure and chemical states of metal nanocatalysts meeting sustainable
development challenges change dramatically, deteriorating the activity
and/or lowering the yield. Theoretically revealing the mechanisms
of oxygen-induced structure evolution and establishing a framework
to distinguish them are vital to improving the operando stability
and rational design of metal nanocatalysts. Here, we studied the oxygen-induced
disintegration and Ostwald ripening of Ni, Cu, Pt, Pd, and Ag nanoparticles
on TiO2(110) using first-principles-based thermodynamic
and kinetic simulations. It was found that oxygen promotes Ostwald
ripening via the formation of Ag/Ag–O and Pd intermediates
on the support and volatile gaseous PtO2 complexes, induces
disintegration of Ni nanoparticles to Ni–O complexes, and leads
to the formation of copper oxide. These differences in the deactivation
pathways can be attributed to the dependence of the ripening activation
energies and disintegration free energies on the interaction between
metal atoms/complexes and TiO2(110). Revealed knowledge
and corresponding models provide valuable insights into the general
mechanisms governing the structural evolution of supported nanocatalysts
under reaction conditions.
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