The structure of rhodium deposited on a well-ordered TiO2(110)-(1 x 2)
surface in the submonolayer region and the effect of annealing were s
tudied by scanning tunneling microscopy and Auger electron spectrometr
y. Deposition of Rh at low coverage gave nanosize (diameter of 1-3 nm)
bumpy structures as a result of 3D particle formation. This process r
oughens the surface considerably. No further radical change in the sur
face morphology was observed at 0.10-1.0 ML (ML=monolayer). Following
annealing of the Rh/TiO2(110)-(1 x 2) system, three different processe
s can be distinguished: (i) the encapsulation of Rh particles in the t
emperature range 500-700 K as indicated by the decrease of the relativ
e AES signal of Rh by 40%. This process is not accompanied by apprecia
ble changes in STM images at higher Rh coverages, but results in an in
crease of the volume of outrising structures at very low Rh deposition
(0.01 ML). (ii) An increase in the size of nanoparticles between 700
and 900 K, indicating their coalescence. The extent of this process de
pended on the amount of the deposited Rh. (iii) The separation of the
3-5 nm diameter and 3-5 atomic-layers thick Rh crystallites (with thei
r (111) plane parallel to the substrate) from titania above 1100 K, wh
ich again exhibits a well-ordered (1 x 2) terrace structure. The evalu
ation of STM images at different Rh coverages led to the conclusion th
at this latter process is probably due to the de-encapsulation of the
encapsulated Rh crystallites.