QCD critical surface from constant entropy contours

Abstract

We provide the first mapping of the critical surface in (2+1)-flavor QCD in the full (T,μB,μQ,μS) space, anchored on lattice QCD results at vanishing chemical potentials and obtained within an expansion along contours of constant entropy density. In the pure μB direction, this framework yields a critical point at (Tc,μB,c) (114,\, 602) MeV. Here we extend the construction to arbitrary directions in the three-dimensional chemical-potential space, parametrized by spherical coordinates (μ,θ,φ), with the radial expansion truncated at O(μ2). The resulting two-dimensional surface carries a direction-dependent critical temperature Tc(θ,φ) and baryochemical potential μB,c(θ,φ), which quantify the shift of the critical point relative to the pure μB direction. We find that μB,c increases by 40-100 MeV along the approximately strangeness neutral direction [μS ≈ (0.15--0.33)\, μB, μQ ≈ 0] relevant for heavy-ion collisions, while the critical temperature stays essentially unchanged. In the charge-neutral, weak-equilibrium direction~[μQ ≈ -(0.05--0.1) \,μB, μS = 0] relevant for neutron star mergers, the critical point, and the associated first-order phase transition, remain present at essentially the same location in the (T,μB) plane. We find no evidence for a critical point at large isospin densities, |μQ| / μB 1, relevant for cosmic trajectories in the early Universe, nor along the pure electric-charge or strangeness directions, at least outside the regions where pion or kaon condensation may occur.