Electronic and geometric structure of doped rare-gas clusters:: surface, site and size effects studied with luminescence spectroscopy

The electronic and geometric structure of rare gas clusters doped with rare-gas atoms Rg = Xe, Kr or Ar is investigated with fluorescence excitation spectroscopy in the VUV spectral range. Several absorption bands are observed in the region of the first electronic excitations of the impurity atoms, which are related to the lowest spin-orbit split atomic P-3(1) and P-1(1) states. Due to influence of surrounding atoms of the cluster, the atomic lines are shifted to the blue and broadened (electronical cage effect). From the known interaction potentials and the measured spectral shifts the coordination of the impurity atom in Ar-N, Kr-N, Ne-N and He-N could be studied in great detail. In the interior of Kr-N and Ar-N the Xe atoms are located in substitutional sites with 12 nearest neighbours and internuclear distances comparable to that of the host matrix. In Ne-N and He-N the cluster atoms (18 and 22, respectively) arrange themselves around the Xe impurity with a bondlength comparable to that of the heteronuclear dimer. The results confirm that He clusters are liquid while Ne clusters are solid for N >= 300. Smaller Ne clusters exhibit a liquid like behaviour. When doping is strong, small Rg(m)-clusters (Rg = Xe, Kr, Ar, m <= 10(2)) are formed in the interior sites of the host cluster made of Ne or He. Specific electronically excited states, assigned to interface excitons are observed. Their absorption bands appear and shift towards lower energy when the cluster size m increases, according to the Frenkel exciton model. The characteristic bulk excitons appear in the spectra, only when the cluster radius exceeds the penetration depth of the interface exciton, which can be considerably larger than that in free Rg(m) clusters. This effect is sensitive to electron affinities of the guest and the host cluster.