Cb. Wang et Ct. Yeh, EFFECTS OF PARTICLE-SIZE ON THE PROGRESSIVE OXIDATION OF NANOMETER PLATINUM BY DIOXYGEN, Journal of catalysis (Print), 178(2), 1998, pp. 450-456
Platinum particles in nanometer size were dispersed on the gamma-Al2O3
support by the impregnation technique. Oxidation phenomena of the sup
ported particles with dioxygen were pursued by a simultaneous TG-DSC t
echnique. Observed extent of oxidation varies in four consecutive step
s, i.e., adsorption of oxygen on the surface of supported platinum cry
stallites at ambient or lower temperatures, reconstruction of platinum
surface for extended accommodation of oxygen above 300 K, formation o
f a stable surface layer of platinum oxides about 750 K, and desorptio
n of oxygen and/or platinum dioxide over 800 K, while raising the temp
erature. Measured heat of oxidation (-Q(ox)) generally decreases with
the extent of oxidation. The particle size (d) of dispersed platinum h
as a profound effect on the oxidation. The species of surface platinum
oxide formed at 770 K was (PtO2)-O-s [-Delta H-f = 190 kJ (mol O-2)(-
1)] as d < 1.3 nm but became (PtO)-O-s [-Delta H-f = 169 kJ (mol O-2)-
1] On d > 2.0 nm. The heat of dioxygen adsorption (Delta H-ad) at T <
300 K could be also correlated with the average diameter (d) of suppor
ted platinum according to -Delta H-ad [kJ (mol O-2)(-1)] = 406 - 81 d/
nm when the platinum diameter was less than 2.5 nm. (C) 1998 Academic
Press.