posted on 2024-10-25, 15:04authored byAntonio J. Martínez-Galera, Rocío Molina-Motos, José M. Gómez-Rodríguez
Being able to access
the rich atomic-scale phenomenology, which
occurs during the reactions pathways, is a pressing need toward the
pursued knowledge-based design of more efficient nanocatalysts, precisely
tailored atom by atom for each reaction. However, to reach this goal
of achieving maximum optimization, it is mandatory, first, to address
how exposure to the experimental conditions, which will be needed
to activate the processes, affects the internal configuration of the
nanoparticles at the atomic level. In particular, the most critical
experimental parameter is probably the temperature, which among other
unwanted effects can induce nanocatalyst aggregation. This work highlights
the high potential of experimental techniques such as the scanning
probe microscopies, which are able to investigate matter in real space
with atomic resolution, to reach the key challenge in heterogeneous
catalysis of achieving access to the atomic-scale processes taking
place in the nanocatalysts. Specifically, the phenomenology occurring
in a nanoparticle system during annealing is studied with atomic precision
by scanning tunneling microscopy. As a result, the existence of an
internal atomic restructuring, occurring already at relatively low
temperatures, within Ir nanoparticles grown over h-BN/Ru(0001) surfaces
is demonstrated. Such restructuration, which reduces the undercoordination
of the outer Ir atoms, is expected to have a significant effect on
the reactivity of the nanoparticles. Going a step further, an internal
restructuring of the nanoparticles during their involvement as catalysts
has also been also identified.