Auger electron angular distributions following excitation or ionization of the I 3d level in methyl iodide

Auger electron spectra following excitation or ionization of the I 3d level in CHI have been recorded with horizontally or vertically plane polarized synchrotron radiation. These spectra have enabled the Auger electron angular distributions, as characterized by the parameter, to be determined. The I 3d photoionization partial cross section of CHI has been calculated with the continuum multiple scattering approach, and the results show that in the photon energy range over which Auger spectra were measured, the I 3d cross section exhibits an atomic-like behavior and is dominated by transitions into the f continuum channel. In this limit, the theoretical value of the alignment parameter () characterizing the core ionized state in an atom becomes constant, independent of photon energy. This theoretical value has been used to obtain the Auger electron intrinsic anisotropy parameters () from the parameters extracted from our normal (non-resonant) molecular Auger spectra. The resulting anisotropy parameters for the MNN transitions in CHI have been compared to those calculated for the corresponding transitions in xenon, and the experimental and theoretical results are in good agreement. Anisotropy parameters have also been measured for the MNN, MNN, and MNO transitions. For the MNN and MNN Auger decays in CHI, the experimentally derived angular distributions do not exhibit the strong dependence on the final ionic state that is predicted for these transitions in xenon. Resonantly excited Auger spectra have been recorded at 620.4 and 632.0 eV, coinciding with the I 3d → σ and 3d → σ transitions, respectively. The resulting Auger electron angular distributions for the MNN and MNN decays were found to exhibit a higher anisotropy than those for the normal process. This is due to the larger photo-induced alignment in the neutral core excited state. For a particular Auger transition, the Auger electron kinetic energy measured in the resonantly excited spectrum is higher than that in the normal spectrum. This shift, due to the screening provided by the electron excited into the σ orbital, has been rationalized by calculating orbital ionization energies of I 3d excited and I 3d ionized states in CHI.