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Strange quark matter from a baryonic approach

Strange quark matter from a baryonic approach
Strange quark matter from a baryonic approach

We construct a model for dense matter based on low-density nuclear matter properties that exhibits a chiral phase transition and that includes strangeness through hyperonic degrees of freedom. Empirical constraints from nuclear matter alone allow for various scenarios, from a strong first-order chiral transition at relatively low densities through a weaker transition at higher densities, even up to a smooth crossover not far beyond the edge of the allowed range. The model parameters can be chosen such that at asymptotically large densities the chirally restored phase contains strangeness and the speed of sound approaches the conformal limit, resulting in a high-density phase that resembles deconfined quark matter. Additionally, if the model is required to reproduce sufficiently massive compact stars, the allowed parameter range is significantly narrowed down, resulting for instance in a very narrow range for the poorly known slope parameter of the symmetry energy, L≃(88-92) MeV. We also find that for the allowed parameter range strangeness does not appear in the form of hyperons in the chirally broken phase and the chiral transition is of first order. Due to its unified approach and relative simplicity - here we restrict ourselves to zero temperature and the mean-field approximation - the model can be used in the future to study dense matter under compact star conditions in the vicinity of the chiral phase transition, for instance to compute the surface tension or to investigate spatially inhomogeneous phases.

2470-0010
Fraga, Eduardo S.
2b3ee6f7-5482-40d1-af8e-d90dff9a72be
Da Mata, Rodrigo
fa6b1a96-8508-43b2-9bb2-08bb380af62d
Pitsinigkos, Savvas
b6097496-ae88-41a2-8cd5-43f1323c7b8a
Schmitt, Andreas
1765159f-255f-45e7-94ea-58c1c883d65f
Fraga, Eduardo S.
2b3ee6f7-5482-40d1-af8e-d90dff9a72be
Da Mata, Rodrigo
fa6b1a96-8508-43b2-9bb2-08bb380af62d
Pitsinigkos, Savvas
b6097496-ae88-41a2-8cd5-43f1323c7b8a
Schmitt, Andreas
1765159f-255f-45e7-94ea-58c1c883d65f

Fraga, Eduardo S., Da Mata, Rodrigo, Pitsinigkos, Savvas and Schmitt, Andreas (2022) Strange quark matter from a baryonic approach. Physical Review D, 106 (7), [074018]. (doi:10.1103/PhysRevD.106.074018).

Record type: Article

Abstract

We construct a model for dense matter based on low-density nuclear matter properties that exhibits a chiral phase transition and that includes strangeness through hyperonic degrees of freedom. Empirical constraints from nuclear matter alone allow for various scenarios, from a strong first-order chiral transition at relatively low densities through a weaker transition at higher densities, even up to a smooth crossover not far beyond the edge of the allowed range. The model parameters can be chosen such that at asymptotically large densities the chirally restored phase contains strangeness and the speed of sound approaches the conformal limit, resulting in a high-density phase that resembles deconfined quark matter. Additionally, if the model is required to reproduce sufficiently massive compact stars, the allowed parameter range is significantly narrowed down, resulting for instance in a very narrow range for the poorly known slope parameter of the symmetry energy, L≃(88-92) MeV. We also find that for the allowed parameter range strangeness does not appear in the form of hyperons in the chirally broken phase and the chiral transition is of first order. Due to its unified approach and relative simplicity - here we restrict ourselves to zero temperature and the mean-field approximation - the model can be used in the future to study dense matter under compact star conditions in the vicinity of the chiral phase transition, for instance to compute the surface tension or to investigate spatially inhomogeneous phases.

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Strange quark matter from a baryonic approach - Accepted Manuscript
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Accepted/In Press date: 13 September 2022
Published date: 1 October 2022
Additional Information: Funding Information: We thank A. Haber and D. Rischke for helpful comments and discussions. E. S. F. is partially supported by CAPES (Finance Code 001), CNPq, FAPERJ, and INCT-FNA (Process No. 464898/2014-5). R. M. thanks CNPq for financial support. Publisher Copyright: © 2022 American Physical Society.

Identifiers

Local EPrints ID: 472680
URI: http://eprints.soton.ac.uk/id/eprint/472680
ISSN: 2470-0010
PURE UUID: a09b66b8-3af7-4ea1-946a-dcef38befa30
ORCID for Andreas Schmitt: ORCID iD orcid.org/0000-0003-2858-4450

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Date deposited: 14 Dec 2022 17:34
Last modified: 17 Mar 2024 03:40

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Contributors

Author: Eduardo S. Fraga
Author: Rodrigo Da Mata
Author: Savvas Pitsinigkos
Author: Andreas Schmitt ORCID iD

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