Universe, Vol. 11, Pages 172: Neutron Star Inner Crust at Finite Temperatures: A Comparison Between Compressible Liquid Drop and Extended Thomas–Fermi Approaches

Greenberg May 27, 2025 in News - 1 Minute

Universe, Vol. 11, Pages 172: Neutron Star Inner Crust at Finite Temperatures: A Comparison Between Compressible Liquid Drop and Extended Thomas–Fermi Approaches

Universe doi: 10.3390/universe11060172

Authors:
Guilherme Grams
Nikolai N. Shchechilin
Théau Diverrès
Anthea F. Fantina
Nicolas Chamel
Gulminelli

We investigate the effects of temperature on the properties of the inner crust of a non-accreting neutron star. To this aim, we employ two different treatments: the compressible liquid drop model (CLDM) and the temperature-dependent extended Thomas&ndash;Fermi (TETF) method. Our systematic comparison shows an agreement between the two methods on their predictions for the crust thermodynamic properties. We find that the CLDM description can also reproduce reasonably well the TETF composition especially if the surface energy is optimized on the ETF calculation. However, the neglect of neutron skin in CLDM leads to an overestimation of the proton radii.

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Guilherme Grams www.mdpi.com

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