How neutron star properties disfavor a nuclear chiral density wave
How neutron star properties disfavor a nuclear chiral density wave
Cold and dense matter may break rotational symmetry spontaneously and thus form an anisotropic phase in the interior of neutron stars. We consider the concrete example of an anisotropic chiral condensate in the form of a chiral density wave. Employing a nucleon-meson model and taking into account fermionic vacuum fluctuations, we improve and extend previous results by imposing the conditions of electric charge neutrality and electroweak equilibrium, by allowing for a more general form of the vector meson self-interactions, and by including properties of pure neutron matter into the fit of the model parameters. We find that the conditions inside neutron stars postpone the onset of the chiral density wave to larger densities compared to isospin-symmetric nuclear matter. While this still allows for the construction of stars with an anisotropic core, we find that the chiral density wave is energetically preferred only in a corner of the parameter space where matter is too soft to generate stars with realistic masses. Therefore, taking into account constraints from astrophysical data, our calculation predicts an isotropic neutron star core.
Papadopoulos, Orestis
cbe11d3d-9a9b-49a6-afcb-1b287242cbfd
Schmitt, Andreas
1765159f-255f-45e7-94ea-58c1c883d65f
Papadopoulos, Orestis
cbe11d3d-9a9b-49a6-afcb-1b287242cbfd
Schmitt, Andreas
1765159f-255f-45e7-94ea-58c1c883d65f
Papadopoulos, Orestis and Schmitt, Andreas
(2025)
How neutron star properties disfavor a nuclear chiral density wave.
Phys.Rev.D, 111 (3), [034010].
(doi:10.1103/PhysRevD.111.034010).
Abstract
Cold and dense matter may break rotational symmetry spontaneously and thus form an anisotropic phase in the interior of neutron stars. We consider the concrete example of an anisotropic chiral condensate in the form of a chiral density wave. Employing a nucleon-meson model and taking into account fermionic vacuum fluctuations, we improve and extend previous results by imposing the conditions of electric charge neutrality and electroweak equilibrium, by allowing for a more general form of the vector meson self-interactions, and by including properties of pure neutron matter into the fit of the model parameters. We find that the conditions inside neutron stars postpone the onset of the chiral density wave to larger densities compared to isospin-symmetric nuclear matter. While this still allows for the construction of stars with an anisotropic core, we find that the chiral density wave is energetically preferred only in a corner of the parameter space where matter is too soft to generate stars with realistic masses. Therefore, taking into account constraints from astrophysical data, our calculation predicts an isotropic neutron star core.
Text
2411.08023v2
- Accepted Manuscript
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e-pub ahead of print date: 11 February 2025
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Local EPrints ID: 499818
URI: http://eprints.soton.ac.uk/id/eprint/499818
ISSN: 2470-0010
PURE UUID: 321bf3d8-80b4-45fd-a4ba-dcf4dfafc64c
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Date deposited: 07 Apr 2025 16:32
Last modified: 08 Apr 2025 01:48
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Author:
Orestis Papadopoulos
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