Relativistic evaluation of the two-photon decay of the metastable 1s2 2s 2p~3P0 state in berylliumlike ions with an active-electron model

Abstract

The two-photon 1s2 2s 2p~3P0 → 1s2 2s2 1S0 transition in berylliumlike ions is theoretically investigated within a full relativistic framework and a second-order perturbation theory. We focus our analysis on how electron correlation, as well as the negative-energy spectrum can affect the forbidden E1M1 decay rate. For this purpose we include the electronic correlation by an effective potential and within an active-electron model. Due to its experimental interest, evaluation of decay rates are performed for berylliumlike xenon and uranium. We find that the negative-energy contribution can be neglected in the present decay rate. On the other hand, if contributions of electronic correlation are not carefully taken into account, it may change the lifetime of the metastable state by 20\%. By performing a full-relativistic jj-coupling calculation, we found discrepancies for the decay rate of an order of 2 compared to non-relativistic LS-coupling calculations, for the selected heavy ions.