Complex Saddle Points and Disorder Lines in QCD at finite temperature and density

TL;DR

This paper investigates complex saddle points in QCD at finite temperature and density, highlighting their role in the sign problem, and explores their effects on Polyakov loop behavior and disorder lines, with implications for simulations and experiments.

Contribution

It introduces a comprehensive analysis of complex saddle points in QCD models, linking them to observable phenomena like disorder lines and Polyakov loop differences.

Findings

A single dominant complex saddle point is necessary for consistent modeling.

Disorder lines are found near critical and crossover regions.

Differences in Polyakov loop expectations are confined to small regions in the phase diagram.

Abstract

The properties and consequences of complex saddle points are explored in phenomenological models of QCD at non-zero temperature and density. Such saddle points are a consequence of the sign problem, and should be considered in both theoretical calculations and lattice simulations. Although saddle points in finite-density QCD are typically in the complex plane, they are constrained by a symmetry that simplifies analysis. We model the effective potential for Polyakov loops using two different potential terms for confinement effects, and consider three different cases for quarks: very heavy quarks, massless quarks without modeling of chiral symmetry breaking effects, and light quarks with both deconfinement and chiral symmetry restoration effects included in a pair of PNJL models. In all cases, we find that a single dominant complex saddle point is required for a consistent description of the model. This saddle point is generally not far from the real axis; the most easily noticed effect is a difference between the Polyakov loop expectation values $\left\langle {\rm Tr}_{F}P\right\rangle $ and $\left\langle {\rm Tr}_{F}P^{\dagger}\right\rangle $, and that is confined to small region in the $\mu-T$ plane. In all but one case, a disorder line is found in the region of critical and/or crossover behavior. The disorder line marks the boundary between exponential decay and sinusoidally modulated exponential decay of correlation functions. Disorder line effects are potentially observable in both simulation and experiment. Precision simulations of QCD in the $\mu-T$ plane have the potential to clearly discriminate between different models of confinement.