The proto-neutron star inner crust in the liquid phase

Thi, Hoa Dinh; Fantina, Anthea; Gulminelli, F.

doi:10.1051/0004-6361/202245061

A&A

2023

DOI: 10.1051/0004-6361/202245061

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The proto-neutron star inner crust in the liquid phase

Hoa Dinh Thi

Anthea Fantina

F. Gulminelli

Abstract: Context. The crust of a neutron star is known to melt at a temperature that increases with increasing matter density, up to about 1010 K. At such high temperatures and beyond, the crustal ions are put into collective motion and the associated entropy contribution can affect both the thermodynamic properties and the composition of matter. Aims. We studied the importance of this effect in different thermodynamic conditions relevant to the inner crust of the proto-neutron star, both at beta equilibrium and in the… Show more

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Cited by 3 publications

References 97 publications

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The proto-neutron star inner crust in a multi-component plasma approach

Thi¹,

Fantina²,

Gulminelli³

2023

A&A

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Context. Proto-neutron stars are born hot, with temperatures exceeding a few times 1010 K. In these conditions, the crust of the proto-neutron star is expected to be made of a Coulomb liquid and composed of an ensemble of different nuclear species. Aims. In this work, we perform a study of the beta-equilibrated proto-neutron-star crust in the liquid phase in a self-consistent multi-component approach. This also allows us to perform a consistent calculation of the impurity parameter, which is often taken as a free parameter in cooling simulations. Methods. To this aim, we developed a self-consistent multi-component approach at finite temperature using a compressible liquid-drop description of the ions, with surface parameters adjusted to reproduce experimental masses. The treatment of the ion centre-of-mass motion was included through a translational free-energy term accounting for in-medium effects. The results of the self-consistent calculations of the multi-component plasma are systematically compared with those performed in a perturbative treatment as well as in the one-component plasma approximation. Results. We show that the inclusion of non-linear mixing terms arising from the ion centre-of-mass motion leads to a breakdown of the ensemble equivalence between the one-component and multi-component approach. Our findings also illustrate that the abundance of light nuclei becomes important and eventually dominates the whole distribution at higher density and temperature in the crust. This is reflected in the impurity parameter, which, in turn, may have a potential impact on neutron-star cooling. For practical application to astrophysical simulations, we also provide a fitting formula for the impurity parameter in the proto-neutron-star inner crust. Conclusions. Our results obtained within a self-consistent multi-component approach show important differences in the prediction of the proto-neutron-star composition with respect to those obtained with a one-component approximation or a perturbative multi-component approximation, particularly in the deeper region of the crust. This highlights the importance of a full, self-consistent multi-component plasma calculation for reliable predictions of the proto-neutron-star crust composition.

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The proto-neutron star inner crust in a multi-component plasma approach

Thi¹,

Fantina²,

Gulminelli³

2023

A&A

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Time-Dependent Nuclear Energy-Density Functional Theory Toolkit for Neutron Star Crust: Dynamics of a Nucleus in a Neutron Superfluid

Pęcak,

Zdanowicz,

Chamel

et al. 2024

Phys. Rev. X

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We present a new numerical tool designed to probe the dense layers of neutron star crusts. It is based on the time-dependent Hartree-Fock-Bogoliubov theory with generalized Skyrme nuclear energy-density functionals of the Brussels-Montreal family. We use it to study the time evolution of a nucleus accelerating through superfluid neutron medium in the inner crust of a neutron star. We extract an effective mass in the low velocity limit. We observe a threshold velocity and specify mechanisms of dissipation: phonon emission, Cooper pairs breaking, and vortex rings creation. These microscopic effects are of key importance for understanding various neutron star phenomena. Moreover, the mechanisms we describe are general and apply also to other fermionic superfluids interacting with obstacles like liquid helium or ultracold gases. Published by the American Physical Society 2024

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Light clusters in the liquid proto-neutron star inner crust

Dinh Thi,

Fantina,

Gulminelli

2023

Eur. Phys. J. A

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The proto-neutron star inner crust in the liquid phase

Cited by 3 publications

References 97 publications

The proto-neutron star inner crust in a multi-component plasma approach

The proto-neutron star inner crust in a multi-component plasma approach

Time-Dependent Nuclear Energy-Density Functional Theory Toolkit for Neutron Star Crust: Dynamics of a Nucleus in a Neutron Superfluid

Light clusters in the liquid proto-neutron star inner crust

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