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Simulating neutron stars with a flexible enthalpy-based equation of state parametrization in SpECTRE

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arxiv 2301.13818 v2 pith:3ULDCTI6 submitted 2023-01-31 astro-ph.HE gr-qc

Simulating neutron stars with a flexible enthalpy-based equation of state parametrization in SpECTRE

classification astro-ph.HE gr-qc
keywords parametrizationenthalpyneutronmodelsnuclearperformancesimulationscomputational
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Numerical simulations of neutron star mergers represent an essential step toward interpreting the full complexity of multimessenger observations and constraining the properties of supranuclear matter. Currently, simulations are limited by an array of factors, including computational performance and input physics uncertainties, such as the neutron star equation of state. In this work, we expand the range of nuclear phenomenology efficiently available to simulations by introducing a new analytic parametrization of cold, beta-equilibrated matter that is based on the relativistic enthalpy. We show that the new \emph{enthalpy parametrization} can capture a range of nuclear behavior, including strong phase transitions. We implement the enthalpy parametrization in the \texttt{SpECTRE} code, simulate isolated neutron stars, and compare performance to the commonly used spectral and polytropic parametrizations. We find comparable computational performance for nuclear models that are well represented by either parametrization, such as simple hadronic EoSs. We show that the enthalpy parametrization further allows us to simulate more complicated hadronic models or models with phase transitions that are inaccessible to current parametrizations.

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