Continuity equation and local gauge invariance for the N3LO nuclear Energy Density Functionals

TL;DR

This paper investigates the relationship between the continuity equation and gauge invariance in the advanced N3LO nuclear energy density functional, establishing conditions for their compatibility across different spin-isospin channels.

Contribution

It derives specific constraints on the N3LO functional's coupling constants ensuring the validity of the continuity equation and links this to gauge invariance principles.

Findings

Four sets of constraints on coupling constants were identified.

Continuity equation validity is equivalent to local gauge invariance.

Invariance under local rotations is required for vector and isovector channels.

Abstract

Background: The next-to-next-to-next-to-leading order (N3LO) nuclear energy density functional extends the standard Skyrme functional with new terms depending on higher-order derivatives of densities, introduced to gain better precision in the nuclear many-body calculations. A thorough study of the transformation properties of the functional with respect to different symmetries is required, as a step preliminary to the adjustment of the coupling constants. Purpose: Determine to which extent the presence of higher-order derivatives in the functional can be compatible with the continuity equation. In particular, to study the relations between the validity of the continuity equation and invariance of the functional under gauge transformations. Methods: Derive conditions for the validity of the continuity equation in the framework of time-dependent density functional theory. The conditions apply separately to the four spin-isospin channels of the one-body density matrix. Results: We obtained four sets of constraints on the coupling constants of the N3LO energy density functional that guarantee the validity of the continuity equation in all spin-isospin channels. In particular, for the scalar-isoscalar channel, the constraints are the same as those resulting from imposing the standard U(1) local-gauge-invariance conditions. Conclusions: Validity of the continuity equation in the four spin-isospin channels is equivalent to the local-gauge invariance of the energy density functional. For vector and isovector channels, such validity requires the invariance of the functional under local rotations in the spin and isospin spaces.