Self-energy correction to the E1 transition amplitudes in hydrogen-like ions
Abstract
We present calculations of the self-energy correction to the E1 transition amplitudes in hydrogen-like ions, performed to all orders in the nuclear binding strength parameter. Our results for the 1s-2p1/2 transition for the hydrogen isoelectronic sequence show that the perturbed-orbital part of the self-energy correction provides the dominant contribution, accounting for approximately 99\% of the total correction for this transition. Detailed calculations were performed for ns-n'p and np-n'd transitions in H-like caesium. We conclude that the perturbed-orbital part remains dominant also for other ns-n'p transitions, whereas for the np-n'd matrix elements this dominance no longer holds. Consequently, the self-energy corrections for the np-n'd one-electron matrix elements cannot be well reproduced by means of effective QED operators constructed for energy levels.
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