Large-scale multiconfiguration Dirac-Hartree-Fock calculations for astrophysics: n=4 levels in P-like ions from Mn~XI to Ni~XIV

Abstract

Using the multiconfiguration Dirac-Hartree-Fock and the relativistic configuration interaction methods, a consistent set of transition energies and radiative transition data for the lowest 546 (623, 701, 745) states of the 3p4 3d, 3s 3p2 3d2, 3s 3p3 4p, 3s 3p4, 3s2 3d3, 3s2 3p2 3d, 3s2 3p2 4d, 3s2 3p2 4s, 3p3 3d2, 3p5, 3s 3p 3d3, 3s 3p3 3d, 3s 3p3 4s, 3s2 3p 3d2, %3s2 3p2 4f, 3s2 3p2 4p, 3s2 3p3 configurations in Mn~XI (Fe~XII, Co~XIII, Ni~XIV) is provided. The comparison between calculated excitation energies for the n=4 states and available experimental values for Fe XII indicate that the calculations are highly accurate, with uncertainties of only a few hundred cm-1. Lines from these states are prominent in the soft X-rays. With the present calculations, several recent new identifications are confirmed. Other identifications involving 3p2 4d levels in Fe~XII that were found questionable are discussed and a few new assignments are recommended. As some n=4 states of the other ions also show large discrepancies between experimental and calculated energies, we reassess their identification. The present study provides highly accurate atomic data for the n=4 states of P-like ions of astrophysical interest, for which experimental data are scarce.