The BCS pairing gap in the on-shell limit of the Similarity Renormalization Group

Abstract

The pairing gap plays a fundamental role in the nuclear many-body problem and many large scale and accurate mass formula fits suggest the smooth nuclear mass dependence 6(1)~ A-1/3~ MeV in the liquid drop model which lacks a theoretical motivation. Within the BCS theory we analyze the impact of phase equivalent interactions on the pairing gap for a translational invariant many-fermion system such as nuclear and neutron matter. To that end we use explicitly the Similarity Renormalization Group (SRG) transformations. We show that in the on-shell and continuum limits the pairing gap vanishes. For finite size systems the pairing gap can be computed directly from the scattering phase-shifts by the formula nn (pF) = εF ~ δ^1S0nn(pF) /π ~ , where pF is the Fermi momentum and εF the level spacing at the Fermi energy which for the harmonic oscillator shell model becomes εF= ω 41 ~ A-1/3~ MeV, so that nn (pF) 4 ~ A-1/3~ MeV ~ . The comparison with double differences from binding energies of stable nuclei is satisfactory and the discrepancy with the large scale analysis may be attributed to the lack of three-body forces. Nevertheless, the on-shell two-body interaction provides a basis for the c~A-1/3 dependency and accounts for 75\% of the coefficient c.