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Equation of State Constraints from Nuclear Physics, Neutron Star Masses, and Future Moment of Inertia Measurements

S. K. Greif, K. Hebeler, J. M. Lattimer, C. J. Pethick, A. Schwenk

2020The Astrophysical Journal73 citationsDOIOpen Access PDF

Abstract

Abstract We explore constraints on the equation of state (EOS) of neutron-rich matter based on microscopic calculations up to nuclear densities and observations of neutron stars. In a previous work we showed that predictions based on modern nuclear interactions derived within chiral effective field theory and the observation of two-solar-mass neutron stars result in a robust uncertainty range for neutron star radii and the EOS over a wide range of densities. In this work we extend this study, employing both the piecewise polytrope extension from Hebeler et al. as well as the speed of sound model of Greif et al., and show that moment of inertia measurements of neutron stars can significantly improve the constraints on the EOS and neutron star radii.

Topics & Concepts

PhysicsNeutron starEquation of stateMoment of inertiaPolytropeNeutronNuclear matterRange (aeronautics)r-processWork (physics)PiecewiseNuclear physicsMoment (physics)Classical mechanicsAnsatzGravitationStellar structureComputational physicsStar (game theory)RADIUSField (mathematics)AstrophysicsStatistical physicsNuclear forceGravitational waveCompact starQuantum electrodynamicsNeutron scatteringState (computer science)s-processStarsPulsars and Gravitational Waves ResearchNuclear physics research studiesScientific Research and Discoveries
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