Multipole characteristics of the open-shell electron eigenstates

Abstract

The second moment of the sublevels within the initial state | α SLJ > which constitutes a natural and adequate measure of the crystal-field (CF) effect can be redefined as sigma2=1/(2J+1)Σk Sk2 Ak2, where Sk=[1/(2k+1)Σq|Bkq|2]1/2 is the so-called 2k-pole CF strength, whereas Ak= < α SLJ||C(k)||α SLJ > the reduced matrix element of the k-rank spherical tensor operator. Therefore, the CF effect depends on the sum of products of the two factors representing the identical multipole components of two different charge distributions. The term Ak expresses the asphericity of the central ion open-shell, whereas the term Sk the asphericity of its surroundings. When these two distributions do not fit each other the observed CF splitting can be unexpectedly weak even for considerable values of the total S=(ΣkSk2)1/2 and A=(ΣkAk2)1/2. The tabulated quantities of the Ak(|α SLJ >), as the 2k-pole type asphericities, are the intrinsic characteristics of the electron states revealing their multipolar structure and hence their potential susceptibility to CF splitting separately for each effective multipole.