Localized Modes in the IR Phase of QCD

Abstract

Infrared (IR) dimension function dIR(λ) characterizes the space effectively utilized by QCD quarks at Dirac scale λ, and indirectly the space occupied by glue fields. It was proposed that its non-analytic behavior in thermal infrared phase reflects the separation of QCD system into an IR component and an independent bulk. Here we study the ``plateau modes" in IR component, whose dimensional properties were puzzling. Indeeed, in the recent metal-to-critical scenario of transition to IR phase, this low-dimensional plateau connects the Anderson-like mobility edge λIR=0 in Dirac spectrum with mobility edges λA. For this structure to be truly Anderson-like, plateau modes have to be exponentially localized, implying that both the effective distances Leff Lγ and the effective volumes Veff LdIR in these modes grow slower than any positive power of IR cutoff L. Although γ=0 was confirmed in the plateau, it was found that dIR≈ 1. Here we apply the recently proposed multidimension technique to the problem. We conclude that a plateau mode of pure-glue QCD at UV cutoff a \!=\! 0.085\,fm occupies a subvolume of IR dimension zero with probability at least 0.9999, substantiating this aspect of metal-to-critical scenario to a respective degree.

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