Structure and information measures of few-electron systems under a spherically symmetric Gaussian potential within a density functional approach

Abstract

Energies of H, He-like (Z=2-18) ions, Li, and Be are investigated under a spherically symmetric Gaussian potential through a density functional formalism. The radial Kohn-Sham equation has been solved by invoking a work function-based exchange potential. The effect of electron correlation is analyzed by incorporating two functionals: a local parameterized Wigner functional and a non-linear gradient- and Laplacian-dependent Lee-Yang-Parr (LYP) functional. The generalized pseudospectral method is employed to provide accurate numerical eigenfunctions and eigenvalues. This allows nonuniform, optimal spatial discretization fulfilling the Dirichlet boundary conditions. This work demonstrates a possible manipulation of energy by controlling dot parameters. Apart from ground states, exploratory results are also reported for low-lying excited state 1s2s (1,3S) of He atom. Companion calculations are also performed for various information-theoretic measures, such as Shannon entropy in position (Sr), momentum (Sp) spaces, and Fisher information in position space (Ir). The behavior of correlation functionals in presence of Gaussian potential is examined critically. We find that energy increases, Sr exhibits minima, while Sp, Ir attain maxima for a decrease in the width of potential, whereas an increase in potential depth further amplifies these effects across all properties. The Fisher-Shannon plane reveals a progressive localization as well as the compression of electronic density, and thereby indicates a weakening of relative electron-correlation effects. In the Collin's conjecture, it gives rise to a non-linear loop-like feature. Much of the results are presented here for the first time.