Unusual Features of QCD Low-Energy Modes in IR Phase

Abstract

It was recently proposed that there is a phase in thermal QCD (IR phase) at temperatures well above the chiral crossover, featuring elements of scale invariance in the infrared (IR). Here we study the effective spatial dimensions, dIR, of Dirac low-energy modes in this phase, in the context of pure-glue QCD. Our dIR is based on the scaling of mode support toward thermodynamic limit, and hence is an IR probe. Ordinary extended modes, such as those at high energy, have dIR=3. We find dIR<3 in the spectral range whose lower edge coincides with λIR=0, the singularity of spectral density defining the IR phase, and the upper edge with λA, the previously identified Anderson-like non-analyticity. Details near λIR are unexpected in that only exact zero modes are dIR=3, while a thin spectral layer near zero is dIR=2, followed by an extended layer of dIR=1 modes. With only integer values appearing, dIR may have topological origin. We find similar structure at λA, and associate its adjacent thin layer (dIR >≈ 2) with Anderson-like criticality. Our analysis reveals the manner in which non-analyticities at λIR and λA, originally identified in other quantities, appear in dIR(λ). This dimension structure may be important for understanding the near-perfect fluidity of the quark-gluon medium seen in accelerator experiments. The role of λA in previously conjectured decoupling of IR component is explained.