INNER SHELL SPECTROSCOPY AND RELATIVISTIC ATOM IONIZATION CROSS SECTION BY ELECTRON IMPACT
Summary
The elemental composition of materials in the Transmission Electron Microscope is
probed by inner shell ionization of atoms by a high energetic electron beam. Proper elemental quantification of the material requires detailed knowledge of the electron-atom differential ionization cross section (DCS). In the current work, the cross section is calculated in
the context of relativistic quantum mechanics. Relativistic effects become important due to
the high energy of the electron beam. The atomic dynamics is calculated in a fully relativistic setting, using Dirac-Hartree-Fock (DHF) solutions for the atomic bound and continuum
wavefunctions. The relaxation of the atom due to the ionization by the beam needs to be
taken into account. To address this, a continuum wave is computed in a self-consistent field
of an ion. Non-orthogonality between atomic and ionic wavefunctions leads to additional
corrections. They are shown to be important at low energy of the ionized electron which is
particularly interesting for materials with elements which have close ionization energies