Relativistic and many-body effects in first-row transition-metal negative ions: Three Zn- bound states
Document Type
Article
Publication Date
1-1-1988
Abstract
In this work relativistic and many-body effects in transition-metal ions are treated independently. For the former, we have written an automated program which provides level-dependent (J) structure input (for both the electrostatic and the magnetic portion of the Breit operator) to Desclauxs multiconfigurational Dirac-Fock program. Also, the nonrelativistic treatment of many-body effects for these atoms via the configuration-interaction (CI) technique has been made much more efficient, in part by the removal of unnecessary (through first-order) parents, so as to make computational costs competitive with those associated with smaller species. We predict that all levels of Zn- 3d94s4p36DJ are bound, with the lowest J=(9/2 bound by 0.810 eV and the highest J=1/2 by 0.511 eV, that Zn- 3d104s4p24PJ is bound by 0.169 eV (J=1/2) and 0.136 eV (J=(5/2), and that Zn- 3d104p3 S3/24 is bound by 0.566 eV. The complete fine structure is given as well as the electric dipole oscillator strength for the '44S°transition. All states are found to consist of at least 90% pure LS coupling. Finally, the configuration-interaction program referred to above will soon be modified to do relativistic CI calculations, thus removing the separability assumption. © 1988 The American Physical Society.
Publication Title
Physical Review A
Recommended Citation
Beck, D.
(1988).
Relativistic and many-body effects in first-row transition-metal negative ions: Three Zn- bound states.
Physical Review A,
37(6), 1847-1857.
http://doi.org/10.1103/PhysRevA.37.1847
Retrieved from: https://digitalcommons.mtu.edu/michigantech-p/9912