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Formulating bulk viscosity for neutron star simulations

Thomas Celora, Ian Hawke, P. Hammond, Nils Andersson, G. L. Comer

2022Physical review. D/Physical review. D.35 citationsDOIOpen Access PDF

Abstract

In order to extract the precise physical information encoded in the gravitational and electromagnetic signals from powerful neutron-star merger events, we need to include as much of the relevant physics as possible in our numerical simulations. This presents a severe challenge, given that many of the involved parameters are poorly constrained. In this paper we focus on the role of nuclear reactions. Combining a theoretical discussion with an analysis connecting to state-of-the-art simulations, we outline multiple arguments that lead to a reactive system being described in terms of a bulk viscosity. The results demonstrate that in order to properly account for nuclear reactions, future simulations must be able to handle different regimes where rather different assumptions/approximations are appropriate. We also touch upon the link to models based on the large-eddy-strategy required to capture turbulence.

Topics & Concepts

Statistical physicsViscosityNeutron starFocus (optics)PhysicsNeutronVolume viscosityOrder (exchange)TurbulenceGravitationGravitational waveComputer scienceTheoretical physicsMechanicsClassical mechanicsNuclear physicsAstrophysicsOpticsQuantum mechanicsEconomicsFinancePulsars and Gravitational Waves ResearchGamma-ray bursts and supernovaeMagnetic confinement fusion research
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