For the first time, the shell structure of open-shell nuclei is described in
a fully self-consistent extension of the covariant energy density functional
theory. The approach implies quasiparticle-vibration coupling for superfluid
systems. One-body Dyson equation formulated in the doubled quasiparticle space
of Dirac spinors is solved for nucleonic propagators in tin isotopes which
represent the reference case: the obtained energies of the single-quasiparticle
levels and their spectroscopic amplitudes are in agreement with data. The model
is applied to describe the shell evolution in a chain of superheavy isotopes
292,296,300,304120 and finds a rather stable proton spherical shell
closure at Z = 120. An interplay of the pairing correlations and the
quasiparticle-phonon coupling gives rise for a smooth evolution of the neutron
shell gap between N = 172 and N = 184 neutron numbers. Vibrational corrections
to the alpha decay energies reach several hundred keV and can be either
positive and negative, thus also smearing the shell effects.Comment: 10 pages, 3 figure
