The growth of Ag films on Pt(111) surfaces is studied using low energy
electron diffraction, thermal desorption spectroscopy, X-ray photoele
ctron spectroscopy (XPS), UV photoelectron spectroscopy, work function
and CO adsorption methods. After completion of the first monolayer, A
g grows via a Stranski-Krastanov mechanism at 300 K. On annealing, how
ever, the film morphology changes to a Frank-van der Merwe structure,
at least within the first three monolayers coverage regime. The Ag lay
er growth is pseudomorphic. The binding energies of the Ag 3d 5/2, 3d
3/2, and 3p 3/2 core levels in the first Ag layer on PT(111) are about
0.35 eV lower than observed for bulk Ag. A model in which this is att
ributed to the difference of densities of states at the Fermi level of
the overlayer and substrate metals gives a reasonable fit of the pres
ent and other data on core level binding energies of metal-on-metal sy
stems. Ag atoms in the second and subsequent layers exhibit the bulk 3
d 5/2 core level binding energy. The apparent shift of the respective
XPS peak maximum with Ag coverage is a consequence of a superposition
of signals from the first and consecutive layers. UPS reveals that ann
ealed Ag submonolayers form 2-dimensional islands. CO chemisorption ex
periments with Ag-Pt(111) films suggest that adsorbed Ag atoms block t
he Pt(111) with respect to CO adsorption in a purely geometrical manne
r.