Separation of Infrared and Bulk in Thermal QCD

Abstract

A new thermal regime of QCD, featuring decoupled scale-invariant infrared glue, has been proposed to exist both in pure-glue (Nf=0) and ``real-world" (Nf=2+1 at physical quark masses) QCD. In this IR phase, elementary degrees of freedom flood the infrared, forming a distinct component independent from the bulk. This behavior necessitates non-analyticities in the theory. In pure-glue QCD, such non-analyticities have been shown to arise via Anderson-like mobility edges in Dirac spectra (λ IR \!=\! 0, λA \!≠\! 0), as manifested in the dimension function d IR (λ). Here, we present the first evidence, based on lattice QCD calculation at a=0.105 fm, that this mechanism is also at work in real-world QCD, thus supporting the existence of the proposed IR regime in nature. An important aspect of our results is that, while at T\!=\!234\,MeV we find a dimensional jump between zero modes and lowest near-zero modes very close to unity (d IR \!=\!3 to d IR \!\! 2), similar to the IR phase of pure-glue QCD, at T\!=\!187\,MeV we observe a continuous λ-dependence. This suggests that thermal states just above the chiral crossover are non-analytically (in T) connected to thermal state at T\!=\!234\,MeV, supporting the key original proposition that the transition into the IR regime occurs at a temperature strictly above the chiral crossover.