This thesis presents experimental studies of gas phase molecular relaxation after excitation

with synchrotron photons in the 15-35 eV and in the 70-350 eV regions.

In the 15-35 eV region, molecular relaxation by neutral dissociation processes and non

Franck-Condon effects in N2 and O2 molecules have been studied by means of dispersed fluorescence

and photoelectron spectroscopy experimental techniques, respectively. From the dispersed

fluorescence data, excitation functions for the measured atomic fluorescence spectra have been

obtained. From the recorded photoelectron spectra vibrational branching ratios have been produced.

The results obtained reveal that Rydberg series and singly and doubly excited valence states of the

appropriate symmetry energetically accessible in the studied region and interactions between them

account for most of the observed effects in these two type of experiments.

In the 70-350 eV range, molecular relaxation processes resulting in fragmentation of CD4 and

SF6 after absorption of synchrotron light have been studied by energy resolved electron ion

coincidence technique using a multicoincidence experimental station developed by our group during

the last five years for such type of experiments. The coincidence measurements yielded mass spectra

from which information about the kinematics of the detected fragments has been deduced by means of

Monte Carlo simulations of the experimental peak shapes. The obtained results show completely

different dissociation patterns depending on the molecular electronic states studied. These patterns

reflect the bonding properties of the excited orbitals and they permit the description and in some cases

the identification of the different molecular relaxation pathways observed. The achievements

presented in this thesis exemplify the potential of the multicoincidence station used in the reported

experiments.