Relativistic configuration interaction calculations for electronic states of KrHe+

Relativisuc configuration interaction calculations are described for stx low-lying elertroruc states of J-II. The spearox+ proper~~~ or these states are calculated and compared with available experimental results. 1\_ Intioduction The hydrogen iodide molecule has been of considerable experimental an

Relativistic configuration interaction calculations of the low-lying states (O\*(I), 1.2. O\*(H)) arising from I?=' con@uratio? of BiH and the corresponding h-s states ('z-, 1 A. 'E+) are carried out These states are found to be bound and the calculated spectroscopic properties are compared with the

Ab initio ~on~guration interaction calctdations which employ relativistic effective potentials for Sn are carried out for the X 'Z +, 'I; +, 'A, 'S -, '2 -,31'1, 'II and 'Z + (If) states of SnS. Spectroscopic properties of these states are computed and compared with available experimental results. T

A relativistic configuration interaction method, which can handle a general class of open-shell multiplets as the reference configurations, has been developed by combining the open-shell matrix Dirac-Fock self-consistent field algorithm implemented by Koc and Ishikawa [Phys. Rev. A 49 ( 1994) 7941 w

We present the results of relativistic and non-relativistic self-consistent field and configuration interaction calculations for the gold atom, using the spin-free no-pair Hamiltonian in a basis set expansion. A new basis set for the gold atom is discussed and its results in relativistic and non-rel

An ab initio configuration interaction study including spin-orbit coupling and employing relativistic effective core potentials for both constituent atoms is reported for the lowest lying states of thallium chloride. Good agreement is obtained with measured \(T_{\mathrm{c}}\) values \(\left( \pm 150