Separation of Infrared and Bulk in Thermal QCD

New thermal phase of QCD, featuring scale invariance in the infrared (IR), was proposed to exist both in the pure-glue (N$_f$=0) and the ``real-world" (N$_f$=2+1) settings. Among key aspects of the proposal is that the system in this {\em IR phase} separates into two independent components: the scale-invariant IR part and the non-invariant bulk. Such scenario requires non-analyticities in the theory and, in case of pure-glue QCD, they were found to arise via Anderson-like mobility edges in Dirac spectra ($\lambda_\fir \!=\! 0$, $\pm \lambda_\text{A} \!\neq\! 0$) manifested in dimension function $d_\fir(\lambda)$. Here we present first evidence that this mechanism is also at work in ``real-world QCD" (N$_f$=2+1 theory at physical quark masses and $a\!=\!0.105\,$fm), supporting the existence of the proposed IR regime. Dimensional jump between zero-modes and lowest near-zero modes very close to unity ($d_\fir\!=\!3$ vs $d_\fir \!\simeq \!2$) was found.