QCD phase-transition under the light of Thermofractal

Abstract

The deconfining transition in SU(3) gauge theory, traditionally interpreted through the Gross-Witten-Wadia (GWW) model as a sharp third-order phase transition in the large-Nc limit, appears as a smooth crossover in lattice QCD. This work demonstrates that the transition is topologically smoothed into a crossover by incorporating the fractal momentum space structure inherent to thermofractals. By matching the non-extensive β-function to one-loop QCD results, a fundamental scaling of the thermofractal index q is derived as a function of the number of flavours Nf. It is proven that applying a q-deformed derivative operator Dq to the q-logarithm of the eigenvalue distance results in a non-extensive measure that effectively smears the topological stiffness of the gauge vacuum. A unified master equation for the Polyakov loop L is presented, governed by the thermofractal index q and a single variance parameter σ2(T) that scales as T1/(q-1). The observed phase dynamics are shown to be asymptotic limits of this unified density: a ``soft'' algebraic growth L T11 in the 1D string-like confined regime for Nf=0, and a rapid 1 - L T-21 suppression in the 3D deconfined volume for Nf=3. This approach provides a microscopic foundation for partial deconfinement theory and reproduces lattice QCD data with a reduced 2 ≈ 1.12, offering a rigorous reconciliation between matrix model topology and the continuous QCD crossover.