Probing the QCD Critical End Point with Finite-Size Scaling of Net-Baryon Cumulant Ratios
Abstract
Finite-size scaling (FSS) is applied to net-baryon cumulant ratios C2/C1, C3/C2, C4/C2, C3/C1, and C4/C1 measured in Au+Au collisions over the Beam Energy Scan Phase~I range sNN=7.7--200~GeV to constrain the location and universality class of the QCD critical end point (CEP). Although finite-size and finite-time effects suppress non-monotonic signatures in unscaled data, the FSS analysis reveals a collapse of measurements from different beam energies and centralities onto universal scaling functions. All cumulant ratios collapse under a single, common set of critical exponents and exhibit divergence patterns characteristic o 3D Ising critical behavior. The scaling results indicate a CEP at s CEP≈33.0~GeV, corresponding to μB, CEP≈130~MeV and T CEP≈158.5~MeV. These findings demonstrate that finite-size scaling provides a robust, model-independent framework for accessing critical behavior in finite, dynamically evolving systems, where non-equilibrium baryon-number transport can enhance the experimental visibility of susceptibility-driven fluctuations without modifying the underlying universality class.
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