Isospin Breaking and chiral symmetry restoration

TL;DR

This paper investigates how isospin breaking effects influence chiral symmetry restoration at finite temperature using chiral perturbation theory, deriving sum rules and analyzing susceptibility contributions with implications for lattice QCD.

Contribution

It provides a model-independent analysis of isospin breaking effects on chiral condensates and susceptibilities, including new sum rules and detailed susceptibility behavior near the transition.

Findings

The chiral restoration temperature is unaffected by isospin breaking.

The isospin breaking order parameter increases with temperature.

Disconnected susceptibility diverges as T/M_pi in the chiral limit.

Abstract

We analyze quark condensates and chiral (scalar) susceptibilities including isospin breaking effects at finite temperature $T$. These include $m_u\neq m_d$ contributions as well as electromagnetic ($e\neq 0$) corrections, both treated in a consistent chiral lagrangian framework to leading order in SU(2) and SU(3) Chiral Perturbation Theory, so that our predictions are model independent. The chiral restoration temperature extracted from $<\bar q q>= <\bar u u + \bar d d >$ is almost unaffected, while the isospin breaking order parameter $<\bar u u - \bar d d >$ grows with $T$ for the three-flavour case SU(3). We derive a sum rule relating the condensate ratio $<\bar q q>(e\neq 0)/<\bar q q>(e=0)$ with the scalar susceptibility difference $\chi(T)-\chi(0)$, directly measurable on the lattice. This sum rule is useful also for estimating condensate errors in staggered lattice analysis. Keeping $m_u\neq m_d$ allows to obtain the connected and disconnected contributions to the susceptibility, even in the isospin limit, whose temperature, mass and isospin breaking dependence we analyze in detail. The disconnected part grows linearly, diverging in the chiral (infrared) limit as $T/M_\pi$, while the connected part shows a quadratic behaviour, infrared regular as $T^2/M_\eta^2$ and coming from $\pi^0\eta$ mixing terms. This smooth connected behaviour suggests that isospin breaking correlations are weaker than critical chiral ones near the transition temperature. We explore some consequences in connection with lattice data and their scaling properties, for which our present analysis for physical masses, i.e. beyond the chiral limit, provides a useful model-independent description for low and moderate temperatures.