Self-consistent $O(4)$ model spectral functions from analytically continued FRG flows

TL;DR

This paper develops and compares self-consistent methods for calculating spectral functions in the $O(4)$ model using analytically continued functional renormalization group flows, enabling detailed analysis of resonance properties and decay processes.

Contribution

It introduces a semi-analytic scheme with explicit self-energy parametrizations and a fully self-consistent numerical spectral function approach, advancing spectral function calculations in effective field theories.

Findings

Self-consistency fixes the relation between particle masses and decay thresholds.

The semi-analytic scheme accurately reproduces spectral functions and resonance poles.

The numerical scheme captures three-particle resonance decay processes.

Abstract

In this paper we explore practicable ways for self-consistent calculations of spectral functions from analytically continued functional renormalization group (aFRG) flow equations. As a particularly straightforward one we propose to include parametrizations of self-energies based on explicit analytic one-loop expressions. To exemplify this scheme we calculate the spectral functions of pion and sigma meson of the $O(4)$ model at vanishing temperature in the broken phase. Comparing the results with those from previous aFRG calculations, we explicitly demonstrate how self-consistency at all momenta fixes the tight relation between particle masses and decay thresholds. In addition, the two-point functions from our new semi-analytic FRG scheme have the desired domain of holomorphy built in and can readily be studied in the entire cut-complex frequency plane, on physical as well as other Riemann sheets. This is very illustrative and allows, for example, to trace the flow of the resonance pole of the sigma meson across an unphysical sheet. In order to assess the limitations due to the underlying one-loop structure, we also introduce a fully self-consistent numerical scheme based on spectral representations with scale-dependent spectral functions. The most notable improvement of this numerically involved calculation is that it describes the three-particle resonance decay of an off-shell pion, $\pi^* \to \sigma\pi\to3\pi$. Apart from this further conceptual improvement, overall agreement with the results from the considerably simpler semi-analytic one-loop scheme is very encouraging, however. The latter can therefore provide a sound and practicable basis for self-consistent calculations of spectral functions in more realistic effective theories for warm and dense matter.