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On the deconfinement phase transition in neutron-star mergers

Elias R. Most, L. Jens Papenfort, Veronica Dexheimer, Matthias Hanauske, Horst Stoecker, Luciano Rezzolla

2020The European Physical Journal A95 citationsDOIOpen Access PDF

Abstract

Abstract We study in detail the nuclear aspects of a neutron-star merger in which deconfinement to quark matter takes place. For this purpose, we make use of the Chiral Mean Field (CMF) model, an effective relativistic model that includes self-consistent chiral symmetry restoration and deconfinement to quark matter and, for this reason, predicts the existence of different degrees of freedom depending on the local density/chemical potential and temperature. We then use the out-of-chemical-equilibrium finite-temperature CMF equation of state in full general-relativistic simulations to analyze which regions of different QCD phase diagrams are probed and which conditions, such as strangeness and entropy, are generated when a strong first-order phase transition appears. We also investigate the amount of electrons present in different stages of the merger and discuss how far from chemical equilibrium they can be and, finally, draw some comparisons with matter created in supernova explosions and heavy-ion collisions.

Topics & Concepts

DeconfinementStrangenessPhysicsStrange matterPhase transitionQuantum chromodynamicsParticle physicsPhase (matter)QuarkField (mathematics)Nuclear matterState of matterDegrees of freedom (physics and chemistry)Symmetry (geometry)Equation of stateMean field theoryDense matterPhase diagramElectronState (computer science)QCD matterElementary particleTheoretical physicsSupernovaQuantum electrodynamicsNuclear physicsCondensed matter physicsQuark modelChiral symmetryHyperonMixed phaseQCD vacuumPulsars and Gravitational Waves ResearchHigh-Energy Particle Collisions ResearchGamma-ray bursts and supernovae
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