Abstract EN:

The increasing availability of modern x-ray light sources with high tunability, high brightness and narrow photon-energy bandwidth has allowed a deep understanding of the physics behind light and matter interactions. During my PhD, I investigated experimentally different process of photoexcitation and photoionization of rare gas atoms (Argon and Xenon) and alkali metals (Potassium and Rubidium) by the means of synchrotron radiation. Our experimental setup is a 2m long magnetic bottle time-of-flight spectrometer that collect in coincidence almost all the electrons emitted in the 4π solid angle. We investigate the multiple Auger decay of the potassium 2p core holes which has an electronic configuration similar to Ar with an additional 4s valence electron. We show the spectator role of this electron in the decay mechanism and the enhancement of double and triple Auger rates comparing with the Argon 2p holes decay. We also investigated the multiple Auger decay of the rubidium 3d core holes. Finally, we investigated the core valence double photoionization of Xenon atom 4d-15p-1 which is compared with the direct ionization of Xe+ ions (MAIA experiment). We showed that the core valence double photoionization process will populate the same states that the ones populated by the photoionization of the ions. One should note that this process is very weak compared to the 4d inner shell ionization of Xe atom but thanks to the coincidence technique we are able to clearly separate and disentangle each ionization process. Our experiment confirmed the results of MAIA and allowed us to extract the Auger spectra associated with the decay of these Xe+ ions, when ionized in the 4d shell.