TY - JOUR AB - We map out the QCD crossover line T-c(mu(B))/T-c(0) = 1 - kappa(2) (mu(B)/T-c(0))(2) - kappa(4)(mu(B)/T-c(0))(4) + O(mu(6)(B)) for the first time up to O(mu(4)(B)) for a strangeness neutral system by performing a Taylor expansion of chiral observables in temperature T and chemical potentials mu. At vanishing chemical potential, we report a crossover temperature T-c(0) = (156.5 +/- 1.5) MeV defined by the average of several second-order chiral susceptibilities. For a system with thermal conditions appropriate for a heavy ion collision, we determined a curvature from the subtracted condensate as kappa(2) = 0.0120(20) and from the disconnected susceptibility as kappa(2) = 0.0123(30). The next order kappa(4) is significantly smaller. We also report the crossover temperature as a function of the chemical potentials for: baryon-number, electric charge, strangeness and isospin. Additionally, we find that T-c(mu(B)) is in agreement with lines of constant energy density and constant entropy density. Along this crossover line, we study net baryon-number fluctuations and show that their increase is substantially smaller compared to that obtained in HRG model calculations. Similarly, we analyze chiral susceptibility fluctuations along the crossover line and show that these are constant. We conclude that no signs for a narrowing of the crossover region can be found for baryon chemical potential mu(B) < 250 MeV. DA - 2019 DO - 10.1016/j.nuclphysa.2018.08.025 LA - eng M2 - 847 PY - 2019 SN - 0375-9474 SP - 847-850 T2 - Nuclear Physics A TI - The QCD crossover at zero and non-zero baryon densities from Lattice QCD UR - https://nbn-resolving.org/urn:nbn:de:0070-pub-29341347 Y2 - 2024-12-26T05:50:01 ER -