Pairing Matrix Elements and Pairing Gaps with Bare, Effective and Induced Interactions

Abstract

The dependence on the single-particle states of the pairing matrix elements of the Gogny force and of the bare low-momentum nucleon-nucleon potential vlow-k is studied in the semiclassical approximation for the case of a typical finite, superfluid nucleus (120Sn). It is found that the matrix elements of vlow-k follow closely those of vGogny on a wide range of energy values around the Fermi energy eF, those associated with vlow-k being less attractive. This result explains the fact that around eF the pairing gap Gogny associated with the Gogny interaction (and with a density of single-particle levels corresponding to an effective k-mass mk≈ 0.7 m) is a factor of about 2 larger than low-k,being in agreement with exp= 1.4 MeV. The exchange of low-lying collective surface vibrations among pairs of nucleons moving in time-reversal states gives rise to an induced pairing interaction vind peaked at eF. The interaction (vlow-k+ vind)Zω arising from the renormalization of the bare nucleon-nucleon potential and of the single-particle motion (ω-mass and quasiparticle strength Zω) due to the particle-vibration coupling leads to a value of the pairing gap at the Fermi energy ren which accounts for the experimental value.

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