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Inferring the Equation of State from Neutron Star Observables via Machine Learning

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arxiv 2502.20226 v2 pith:F4J4UA65 submitted 2025-02-27 nucl-th astro-ph.HEastro-ph.SRgr-qchep-ph

Inferring the Equation of State from Neutron Star Observables via Machine Learning

classification nucl-th astro-ph.HEastro-ph.SRgr-qchep-ph
keywords neutronobservablesdensitymassstarstateaccurateagnostic
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We have conducted an extensive study using a diverse set of equations of state (EoSs) to uncover strong relationships between neutron star (NS) observables and the underlying EoS parameters using symbolic regression method. These EoS models, derived from a mix of agnostic and physics-based approaches, considered neutron stars composed of nucleons, hyperons, and other exotic degrees of freedom in beta equilibrium. The maximum mass of a NS is found to be strongly correlated with the pressure and baryon density at an energy density of approximately 800 MeV.fm$^{-3}$. We have also demonstrated that the EoS can be expressed as a function of radius and tidal deformability within the NS mass range 1-2$M_\odot$. These insights offer a promising and efficient framework to decode the dense matter EoS directly from the accurate knowledge of NS observables.

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