Relativistic distorted-wave cross sections for electron-impact excitations of berylliumlike ions
Abstract
Relativistic distorted-wave Born (RDWB) cross sections of Be-like ions for excitations from the ground state 2s2 1S0 to the 2s2p 3P1 and 1P1 states by electron impact are reported for Ne6+ through U88+. Multiconfiguration Dirac-Fock wave functions were used to describe the target-ion states, and the relativistic continuum wave functions were calculated in the field of (frozen) target-ion charge distribution with the configuration-average exchange potential. We found, however, that cross sections hardly changed even if the exchange terms were omitted. In contrast, adding the 2p2 configuration to the ground-state wave function reduced cross sections by 10-60 %. RDWB cross sections were calculated from thresholds to T=10 keV, where T is the incident electron energy. For Z~=25 and above, where Z is the nuclear charge, intermediate coupling mixes the 3P1 and 1P1 states such that the transition to the former becomes practically spin- and electric-dipole allowed, changing the high-T behavior of the excitation cross section. Cross sections are presented in compact fitting formulas that allow interpolations to determine cross sections with high precision for arbitrary Be-like ions (10<=Z<=92) and arbitrary incident energies (T<=10 keV).
- Publication:
-
Physical Review A
- Pub Date:
- May 1989
- DOI:
- Bibcode:
- 1989PhRvA..39.4509Q
- Keywords:
-
- Atomic Excitations;
- Beryllium;
- Electron Impact;
- Metal Ions;
- Dirac Equation;
- Ground State;
- Particle Interactions;
- Wave Functions;
- Atomic and Molecular Physics;
- 34.80.Kw;
- 31.30.Jv;
- 31.20.Tz;
- Electron-ion scattering;
- excitation and ionization;
- Relativistic and quantum electrodynamic effects in atoms and molecules