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Extracting nuclear matter properties from the neutron star matter equation of state using deep neural networks

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arxiv 2209.09085 v2 pith:UDAKGXBT submitted 2022-09-19 nucl-th astro-ph.HEhep-ph

Extracting nuclear matter properties from the neutron star matter equation of state using deep neural networks

classification nucl-th astro-ph.HEhep-ph
keywords matternuclearpropertiesenergymodelaccuracybetacorresponding
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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The extraction of the nuclear matter properties from neutron star (NS) observations is nowadays an important issue, in particular, the properties that characterize the symmetry energy which are essential to describe correctly asymmetric nuclear matter. We use deep neural networks (DNNs) to map the relation between cold $\beta$-equilibrium NS matter and the nuclear matter properties. Assuming a quadratic dependence on the isospin asymmetry for the energy per particle of homogeneous nuclear matter and using a Taylor expansion up to fourth order in the iso-scalar and iso-vector contributions, we generate a dataset of different realizations of $\beta$-equilibrium NS matter and the corresponding nuclear matter properties. The DNN model was successfully trained, attaining great accuracy in the test set. Finally, a real case scenario was used to test the DNN model, where a set of 33 nuclear models, obtained within a relativistic mean field approach or a Skyrme force description, were fed into the DNN model and the corresponding nuclear matter parameters recovered with considerable accuracy, in particular, the standard deviations $\sigma(L_{\text{sym}})= 12.85$ MeV and $\sigma(K_{\text{sat}})= 41.02$ MeV were obtained, respectively, for the slope of the symmetry energy and the nuclear matter incompressibility at saturation.

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