Nuclear structure and the nucleon effective mass: explorations with the versatile KIDS functional

TL;DR

This paper explores the connection between nuclear structure and the equation of state using the versatile KIDS functional, highlighting the impact of effective mass and compression modulus on nuclear resonances.

Contribution

It introduces the KIDS functional framework for linking nuclear matter properties to finite nuclei and investigates the role of effective mass in nuclear excitations.

Findings

Effective mass and compression modulus influence giant resonance energies.

KIDS functional provides a consistent way to connect nuclear matter and finite nuclei.

Effective mass parameters significantly affect the centroid energy of GMR.

Abstract

The connection from the structure and dynamics of atomic nuclei (finite nuclear system) to the nuclear equation of state (thermodynamic limit) is primarily made through nuclear energy-density functional (EDF) theory. Failure to describe both entities simultaneously within existing EDF frameworks means that we have either seriously misjudged the scope of EDF or not fully taken advantage of it. Enter the versatile KIDS Ansatz, which is based on controlled, order-by-order extensions of the nuclear EDF with respect to the Fermi momentum and allows a direct mapping from a given, immutable equation of state to a convenient Skyrme pseudopotential for applications in finite nuclei. A recent proof-of-principle study of nuclear ground-states revealed the subversive role of the effective mass. Here we summarize the formalism and previous results and present further explorations related to giant resonances. As examples we consider the electric dipole polarizability of 68Ni and the giant monopole resonance (GMR) of heavy nuclei, particularly the "fluffiness" of 120Sn. We find that the choice of the effective mass parameters and that of the compression modulus affect the centroid energy of the GMR to comparable degrees.