English

Particle-vibration coupling within covariant density functional theory

Nuclear Theory 2008-11-26 v1

Abstract

Covariant density functional theory, which has so far been applied only within the framework of static and time dependent mean field theory is extended to include Particle-Vibration Coupling (PVC) in a consistent way. Starting from a conventional energy functional we calculate the low-lying collective vibrations in Relativistic Random Phase Approximation (RRPA) and construct an energy dependent self-energy for the Dyson equation. The resulting Bethe-Salpeter equation in the particle-hole (phph) channel is solved in the Time Blocking Approximation (TBA). No additional parameters are used and double counting is avoided by a proper subtraction method. The same energy functional, i.e. the same set of coupling constants, generates the Dirac-Hartree single-particle spectrum, the static part of the residual phph-interaction and the particle-phonon coupling vertices. Therefore a fully consistent description of nuclear excited states is developed. This method is applied for an investigation of damping phenomena in the spherical nuclei with closed shells 208^{208}Pb and 132^{132}Sn. Since the phonon coupling terms enrich the RRPA spectrum with a multitude of phph\otimesphonon components a noticeable fragmentation of the giant resonances is found, which is in full agreement with experimental data and with results of the semi-phenomenological non-relativistic approach.

Keywords

Cite

@article{arxiv.0705.1044,
  title  = {Particle-vibration coupling within covariant density functional theory},
  author = {E. Litvinova and P. Ring and V. Tselyaev},
  journal= {arXiv preprint arXiv:0705.1044},
  year   = {2008}
}
R2 v1 2026-06-21T08:25:59.443Z