Dynamical relativistic RPA calculations predict lower crust-core transition densities and pressures than thermodynamic ones across covariant energy density functionals, resulting in thinner crusts and reduced crustal moment of inertia fractions.
Constraints on the inner edge of neutron star crusts from relativistic nuclear energy density functionals
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abstract
The transition density $n_t$ and pressure $P_t$ at the inner edge between the liquid core and the solid crust of a neutron star are analyzed using the thermodynamical method and the framework of relativistic nuclear energy density functionals. Starting from a functional that has been carefully adjusted to experimental binding energies of finite nuclei, and varying the density dependence of the corresponding symmetry energy within the limits determined by isovector properties of finite nuclei, we estimate the constraints on the core-crust transition density and pressure of neutron stars: $0.086 \ {\rm fm}^{-3} \leq n_t < 0.090 \ {\rm fm}^{-3}$ and $0.3\ {\rm MeV \ fm}^{-3} < P_t \leq 0.76 \ {\rm MeV \ fm}^{-3}$.
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Thermodynamic versus Dynamical Description of the Neutron-Star Crust-Core Instability: Implications for Crustal Observables
Dynamical relativistic RPA calculations predict lower crust-core transition densities and pressures than thermodynamic ones across covariant energy density functionals, resulting in thinner crusts and reduced crustal moment of inertia fractions.