Finite-field calculation of the polarizabilities and hyperpolarizabilities of Al+

Abstract

In this study, accurate static dipole polarizability and hyperpolarizability are calculated for Al+ ground state 3s2 1S0 and excited state 3s3p 3PJ with J=0, 1, 2. The finite-field computations use energies obtained with the relativistic configuration interaction approach and the relativistic coupled-cluster approach. Excellent agreement with previously recommended values is found for the dipole polarizability of Al+ ground state 3s2 1S0 and excited state 3s3p 3P0 as well as the hyperpolarizability of the ground state 3s2 1S0. The recommended values of the dipole polarizability of the Al+ 3s3p 3P1 and 3P2 and the hyperpolarizability of Al+ 3s3p 3P0, 3P1, and 3P2 are also given. The impacts of the relativity and spin-orbit coupling are elucidated by analyzing the angular momentum dependence of the dipole polarizability and the hyperpolarizability and comparing the fully and scalar relativistic calculated data. It is shown that the impact of the relativity and spin-orbit coupling are small for the dipole polarizability but become significant for the hyperpolarizability. Finally, the black-body radiation shifts contributed by the dipole polarizability and hyperpolarizability respectively are evaluated for transitions of Al+ 3s2 1S0 to 3s3p 3PJ with J=0, 1, 2.