Comparative Analysis of Mg$^+$ Properties using Multiconfiguration Dirac-Hartree-Fock and Relativistic Coupled-cluster Methods

We demonstrate behaviors of correlation effects in the calculations of atomic properties through two commonly employed many-body methods; namely multiconfiguration Dirac-Hartree-Fock (MCDHF) and relativistic coupled-cluster (RCC) methods. Particularly, we have bench-marked excitation energies, electric dipole (E1) matrix elements, magnetic dipole hyperfine structure constants ($A_{hf}$), and isotope shift (IS) constants in the singly ionized magnesium (Mg$^+$) systematically at different levels of approximation of both methods. We have also estimated the E1 polarizability of the ground state and lifetimes of the excited states using the E1 matrix elements from both methods. All these results are compared with the experimental values wherever available. We find that the computed results agree well with each other with a few exceptions; particularly the $A_{hf}$ and IS constants from the RCC method are found to agree with the measurements better. This comparison analysis would be useful in evaluating the above-discussed properties in other atomic systems using the MCDHF and RCC methods more reliably.