Estimating the radiative part of QED effects in superheavy nuclear quasimolecules

Abstract

A method for calculating the electronic levels in the compact superheavy nuclear quasi-molecules, based on solving the two-center Dirac equation using the multipole expansion of two-center potential, is developed. For the internuclear distances up to d100~fm such technique reveals a quite fast convergence and allows for computing the electronic levels in such systems with accuracy 10-6 . The critical distances Rcr between the nuclei for 1σg and 1σu electronic levels in the region Z 87-100 are calculated. By means of the same technique the shifts of electronic levels due to the effective interaction UAMM of the electron's magnetic anomaly with the Coulomb field of the closely spaced heavy nuclei are evaluated as a function of the internuclear distance and the charge of the nuclei, non-perturbatively both in Zα and (partially) in α/π. It is shown, that the levels shifts near the lower continuum decrease with the enlarging size of the system of Coulomb sources both in the absolute units and in units of Z4 α5 / π n3. The last result is generalized to the whole self-energy contribution to the level shifts and so to the possible behavior of radiative part of QED-effects with virtual photon exchange near the lower continuum in the overcritical region.