Spectral sum rules and phase transition in strongly coupled QCD

TL;DR

This paper derives spectral sum rules for strongly coupled QCD, revealing a phase transition characterized by a change from a three-mode to a one-mode phase, linked to magnetic scale effects and Lorentz symmetry breaking.

Contribution

It introduces spectral sum rules that incorporate both electric and magnetic scales in strongly coupled QCD, uncovering a novel phase transition mechanism.

Findings

Spectral functions in strongly coupled QCD are continuous and non-analytic in complex energy.

A phase transition occurs from a three-mode to a one-mode phase as coupling increases.

The thermal mass acts as an order parameter, vanishing at large coupling.

Abstract

By incorporating contributions from both the (chromo)electric scale $gT$ and (chromo)magnetic scale $g^2T$, we establish spectral sum rules of quarks for strongly coupled QCD that respect Fermi-Dirac statistics as required by quantum mechanics. In sharp contrast to QED and weakly coupled QCD whose spectral functions consist of discontinuous zero-dimensional (poles) and one-dimensional (branch cuts) non-analytic contributions from real energy $p_0 \in \mathbb{R}$, the derived spectral function for strongly coupled quarks features continuous but non-analytic contributions from complex energy $p_0 \in \mathbb{C}$ that are two-dimensional in nature. In light of the novel sum rules, we uncover an intrinsic QCD transition between a three-mode phase at small coupling and a one-mode phase at large coupling. The transition is induced by the magnetic scale that generates a massless hydro-like mode with the genuine non-Abelian feature of positivity violation and serving as the Goldstone mode of the Lorentz symmetry breaking. The thermal mass serves as an order parameter of the transition and vanishes at large coupling in line with phenomenological predictions from Dyson-Schwinger equations and gauge/gravity duality. This result provides novel insights into the mechanism of the QCD deconfinement transition.