Featured trends in e-+Mn electron elastic scattering

Abstract

The impacts of both exchange interaction and electron correlation, as well as their combined impact, on electron elastic scattering off a semifilled shell Mn(...3d54s2, 6S) atom are theoretically studied in the electron energy range of ε= 0-25 eV. Corresponding elastic scattering phase shifts δ(ε) as well as partial σ(ε) and total σ(ε) cross sections are found to be subject to a strong correlation impact. The latter is shown to be drastically different for oppositely spin-polarized scattered electrons, in some cases, thereby bringing significant differences in corresponding δ(ε)s, σ(ε)s, and σ(ε)s between said electrons. This is proven to be an inherent features of electron scattering off a semifilled shell atom in general. Electron correlation is accounted for in the framework of the self-energy part of the Green function of a scattered electron concept. The latter is calculated both in the second-order perturbation theory in the Coulomb interelectron interaction as well as beyond it by solving the Dyson equation for . The significance of the "Dyson" correlation corrections in e-+Mn scattering is unraveled. They are shown to aggravate noticeably the inherent differences between elastic scattering phase shifts and cross sections of spin-up () and spin-down () polarized electrons scattered off a spin-polarized Mn atom, in some cases. In particular, the existence of a narrow resonant maximum in σ(ε) near ε ≈ 8 eV but the absence of such in σ(ε) in e-+Mn scattering is predicted.