posted on 2023-03-31, 13:34authored byFabio Rasera, Alisson S. Thill, Lívia P. Matte, Gustavo Z. Girotto, Helena V. Casara, Guilherme B. Della Mea, Naira M. Balzaretti, Fernanda Poletto, Carolina Brito, Fabiano Bernardi
The development of thermally stable
nanoparticles is of utmost
importance for applications like catalysis. In particular, Cu nanoparticles
supported on metal oxides are easily deactivated under thermal treatments
at low temperatures by sintering of the Cu nanoparticles. The formation
of thermally stable nanoparticles is typically obtained with secondary
drawbacks. In this study, an alternative method for avoiding sintering
of Cu nanoparticles is proposed. The method is based on the impregnation
of dithiol molecules at the metal oxide support before supporting
the Cu nanoparticles. The dithiol molecules are able to avoid the
Cu nanoparticle diffusion, thus decreasing the coalescence rate. Furthermore,
the Cu nanoparticles are not poisoned during thermal treatments. A
simple model is proposed and numerically studied to estimate the minimal
concentration of dithiol necessary to avoid sintering of the nanoparticles.
The method is not complex, and there is no interference on the original
Cu nanoparticles properties. It opens possibilities for widening the
lifespan of metal nanoparticles supported on metal oxides.