Spectroscopy of calcium deposited on large argon clusters

M. A. Gaveau; M. Briant; P. R. Fournier; J. M. Mestdagh; J. P. Visticot; F. Calvo; S. Baudrand; F. Spiegelman

doi:10.1140/epjd/e2002-00201-5

2022 Impact factor 1.8

Atomic, Molecular, Optical and Plasma Physics

Eur. Phys. J. D 21, 153-161 (2002)
https://doi.org/10.1140/epjd/e2002-00201-5

Spectroscopy of calcium deposited on large argon clusters

M. A. Gaveau¹, M. Briant¹, P. R. Fournier¹, J. M. Mestdagh¹^a, J. P. Visticot¹, F. Calvo², S. Baudrand² and F. Spiegelman²

¹ Laboratoire Francis Perrin (URA 2453 du CNRS) , CEA Saclay, 91191 Gif-sur-Yvette Cedex, France
² Laboratoire de Physique Quantique (UMR 5626 du CNRS) , IRSAMC, Université Paul Sabatier, 118 route de Narbonne, 31062 Toulouse Cedex, France

Corresponding author: ^a jmm@drecam.saclay.cea.fr

Received: 7 May 2002
Published online: 1 October 2002

Abstract

Spectroscopic experiments have been performed, providing emission and excitation spectra of calcium atoms trapped on argon clusters of average size 2 000. The two experimental spectra fall in the vicinity of the calcium resonance line ¹PS₀ at 422.9 nm. The excitation spectrum consists in two bands located on each side of the resonance line of the free calcium. In addition, Monte Carlo calculations, coupled to Diatomics-In-Molecule potentials are employed to simulate the absorption spectrum of a single calcium atom in the environment of a large argon cluster of average size 300. The theoretical absorption spectrum confirms the existence of two bands, and shows that these bands are characteristic of a calcium atom located at the surface of the argon cluster and correspond to the excited 4p orbital of calcium either perpendicular or parallel to the cluster surface. The precise comparison between the shape of the absorption spectrum and that of the fluorescence excitation spectrum shows different intensity ratios. This could suggest the existence of a non adiabatic energy transfer that quenches partly the fluorescence of trapped calcium. Another explanation, although less likely, could be a substantial dependence of the calcium oscillator strength according to the alignment of the calcium excited orbital with respect to the cluster surface. The emission spectrum always shows a band in the red of the resonance line which is assigned to the emission of calcium remaining trapped on the cluster. When exciting the blue band of the excitation spectrum, the emission spectrum shows a second, weak, component that is assigned to calcium atoms ejected from the argon clusters, indicating a competition between ejection and solvation.