The internal entanglement entropy of a proton is similar in magnitude to the Gibbs entropy of the QGP droplet from which the proton formed.
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Bayesian analysis favors a strong first-order phase transition in cold dense QCD matter whose onset lies above the central density of the most massive observed neutron stars.
A van der Waals description with temperature-dependent degeneracy g(T) and effective chemical potential μ(T) reproduces the trace anomaly and its peak near the QCD crossover.
A review of thermal modifications to light and heavy hadron properties via imaginary-time formalism, effective field theories, unitarized approaches, and lattice QCD, with links to heavy-ion phenomenology.
citing papers explorer
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Looking at the Entropy in a Proton through a QGP Lens
The internal entanglement entropy of a proton is similar in magnitude to the Gibbs entropy of the QGP droplet from which the proton formed.
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On the Possibility of a Strong First-Order Phase Transition in Neutron Stars
Bayesian analysis favors a strong first-order phase transition in cold dense QCD matter whose onset lies above the central density of the most massive observed neutron stars.
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Trace anomaly, effective degrees of freedom, and chemical potential effects near the QCD crossover
A van der Waals description with temperature-dependent degeneracy g(T) and effective chemical potential μ(T) reproduces the trace anomaly and its peak near the QCD crossover.
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Hadron properties at finite temperature
A review of thermal modifications to light and heavy hadron properties via imaginary-time formalism, effective field theories, unitarized approaches, and lattice QCD, with links to heavy-ion phenomenology.