The Quenched gA Puzzle in Nuclei & Nuclear Matter and "Pseudo-Conformality" in QCD

Abstract

The long-standing puzzle of the quenched gA in nuclei is shown to have an extremely simple resolution in a renormalization-group (RG) treatment of a hidden local symmetric (HLS) and scale-symmetric (HSS) chiral Lagrangian. It is shown that the Landau-Migdal fixed-point approximation in nuclear matter (or Vlowk in finite nuclei) in RG approach to strong correlations of fermionic hadrons on the Fermi surface exactly reproduces the superallowed Gamow-Teller transitions in the ``Extreme Single-Particle (shell-)Model (ESPM)" in doubly-magic closed shell nuclei. One arrives at the quenching factor q≈ 0.78 giving the quenched gA eff ≈ 1. This resolution exposes scale-chiral symmetry, hidden in QCD in the vacuum, emerging in nuclear matter from low density to high compact-star density. It has important implications on ``first principles" approaches to nuclear physics, such as the role of multi-body exchange currents in weak axial-current matrix elements in nuclei and in neutrinoless double β decays for going Beyond the Standard Model. This resolution could put in serious doubt the most recent improved measurement of the superallowed Gamow-Teller transition in the doubly-magic closed shell nucleus 100Sn which if confirmed would require a `` fundamental quenching" qssb 1/2.

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