Chiral crossover versus chiral density wave in dense nuclear matter
Chiral crossover versus chiral density wave in dense nuclear matter
We employ a model based on nucleonic and mesonic degrees of freedom to discuss the competition between isotropic and anisotropic phases in cold and dense matter. Assuming isotropy, the model exhibits a chiral phase transition which is of second order in the chiral limit and becomes a crossover in the case of a realistic pion mass. This observation crucially depends on the presence of the nucleonic vacuum contribution. Allowing for an anisotropic phase in the form of a chiral density wave can disrupt the smooth crossover. We identify the regions in the parameter space of the model where a chiral density wave is energetically preferred. A high-density reappearance of the chiral density wave with unphysical behavior, as seen in previous studies, is avoided by a suitable renormalization scheme. A nonzero pion mass tends to disfavor the anisotropic phase compared to the chiral limit and we find that, within our model, the chiral density wave is only realized for baryon densities of at least about 6 times nuclear saturation density.
Pitsinigkos, Savvas
b6097496-ae88-41a2-8cd5-43f1323c7b8a
Schmitt, Andreas
1765159f-255f-45e7-94ea-58c1c883d65f
22 January 2024
Pitsinigkos, Savvas
b6097496-ae88-41a2-8cd5-43f1323c7b8a
Schmitt, Andreas
1765159f-255f-45e7-94ea-58c1c883d65f
Pitsinigkos, Savvas and Schmitt, Andreas
(2024)
Chiral crossover versus chiral density wave in dense nuclear matter.
Phys.Rev.D, 109, [014024].
(doi:10.1103/PhysRevD.109.014024).
Abstract
We employ a model based on nucleonic and mesonic degrees of freedom to discuss the competition between isotropic and anisotropic phases in cold and dense matter. Assuming isotropy, the model exhibits a chiral phase transition which is of second order in the chiral limit and becomes a crossover in the case of a realistic pion mass. This observation crucially depends on the presence of the nucleonic vacuum contribution. Allowing for an anisotropic phase in the form of a chiral density wave can disrupt the smooth crossover. We identify the regions in the parameter space of the model where a chiral density wave is energetically preferred. A high-density reappearance of the chiral density wave with unphysical behavior, as seen in previous studies, is avoided by a suitable renormalization scheme. A nonzero pion mass tends to disfavor the anisotropic phase compared to the chiral limit and we find that, within our model, the chiral density wave is only realized for baryon densities of at least about 6 times nuclear saturation density.
Text
2309.01603v3
- Accepted Manuscript
Text
PhysRevD.109.014024
- Version of Record
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Accepted/In Press date: 24 October 2023
Published date: 22 January 2024
Identifiers
Local EPrints ID: 499816
URI: http://eprints.soton.ac.uk/id/eprint/499816
ISSN: 2470-0010
PURE UUID: e7beb81d-d226-4d2f-b8f0-368059111a3e
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Date deposited: 07 Apr 2025 16:31
Last modified: 22 Aug 2025 02:30
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Author:
Savvas Pitsinigkos
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