Autoionization of high- core-excited Rydberg states of alkaline-earth-metal atoms

Abstract

The autoionization of core-excited Rydberg states is theoretically studied for a broad range of principal and angular-momentum quantum numbers n and in alkaline-earth-metal atoms. We combined two theoretical methods to calculate accurate autoionization rates for n=10-65 and =0-45 over the 100 orders of magnitude that they span. The strong interaction between the two valence electrons for low states is treated from first principles with configuration interaction with exterior complex scaling, while at large the weak correlation is described by a perturbative approach and arbitrary-precision floating-point arithmetics. The results, which we benchmark against available experimental data, provide autoionization rates for the Np1/2, 3/2 and, when applicable, (N-1)d3/2, 5/2 ion-core states of Mg, Ca and Sr (N=3-5). Using the extensive set of calculated data, we analyze the dependence of the rates on and identify five general laws of the autoionization of high- states. An empirical formula describing the scaling of the rates with is suggested.