Asymmetric nuclear matter in a parity doublet model with hidden local symmetry

Motohiro, Yuichi; Kim, Youngman; Harada, Masayasu

doi:10.1103/physrevc.92.025201

Cited by 75 publications

(56 citation statements)

References 60 publications

(81 reference statements)

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“…Selected properties of the hadronic equations of state (T = 0, µ C = 0) and their experimental constraints (cf. [34][35][36] As evident from Figure 1, the quark matter EoS differ depending on the choice of hadronic EoS. This difference is constant for a given temperature and charge chemical potential, as to be expected from Equations (31), (35) and (36).…”

Section: The Phase Diagrammentioning

confidence: 54%

Impact of the Nuclear Equation of State on the Stability of Hybrid Neutron Stars

et al. 2019

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We construct a set of equations of state (EoS) of dense and hot matter with a 1st order phase transition from a hadronic system to a deconfined quark matter state. In this two-phase approach, hadrons are described using the relativistic mean field theory with different parametrisations and the deconfined quark phase is modeled using vBag, a bag-type model extended to include vector interactions as well as a simultaneous onset of chiral symmetry restoration and deconfinement. This feature results in a non-trivial connection between the hadron and quark EoS, modifying the quark phase beyond its onset density. We find that this unique property has an impact on the predicted hybrid (quark core) neutron star mass-radius relations.

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Section: The Phase Diagrammentioning

confidence: 54%

Impact of the Nuclear Equation of State on the Stability of Hybrid Neutron Stars

et al. 2019

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“…The properties of hot and/or dense matter including neutron star matter based on the parity doublet structure are widely studied in Refs. [11,[18][19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36]. In [11, 18-22, 24, 26, 28], the authors studied the relation between the chiral invariant mass and the incompressibility K of nuclear matter and their results show that the empirical value K ∼ 240 MeV only when the chiral invariant mass is close to nucleon's mass, m 0 ∼ 900 MeV.…”

Section: Introductionmentioning

confidence: 99%

“…In Ref. [29], six point interaction of scalar mesons was introduced and it was shown that the saturation properties are reproduced for wide region of the chiral invariant mass, i.e. 500 ≤ m 0 ≤ 900 MeV.…”

Section: Introductionmentioning

confidence: 99%

“…For the meson parts, we use the model introduced in Ref. [29]: the six point interaction of the scalar field is introduced and the ω and ρ mesons are included based on the hidden local symmetry [44,45]. We will show that requiring the saturation properties of normal nuclear matter excludes some combinations of two chiral invariant masses.…”

Section: Introductionmentioning

confidence: 99%

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Constraint to chiral invariant masses of nucleons from GW170817 in an extended parity doublet model

Yamazaki

Harada

2019

Phys. Rev. C

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We construct nuclear matter based on an extended parity doublet model including four light nucleons N (939), N (1440), N (1535), and N (1650). We exclude some values of the chiral invariant masses by requiring the saturation properties of normal nuclear matter; saturation density, binding energy, incompressibility, and symmetry energy. We find further constraint to the chiral invariant masses from the tidal deformability determined by the observation of the gravitational waves from neutron star merger GW170817. Our result shows that the chiral invariant masses are larger than about 600 MeV. We also give some predictions on the symmetry energy and the slope parameters in the high density region, which will be measured in future experiments.

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“…In this study, the nucleons are introduced by the twoflavor Parity Doublet Model (PDM) [38][39][40][41][42], and nuclear matter is constructed by the one-loop approximation of the nucleon together with the meson mean fields [43][44][45][46] obtained from the eLSM. In our approach, not only the vacuum properties of nucleons but also the nuclear matter properties such as the saturation density, the binding energy per a nucleon, and the incompressibility are successfully reproduced.…”

Section: Introductionmentioning

confidence: 99%

Mass Modifications of Light Mesons in Nuclear Matter with the Three Flavor Extended Linear Sigma Model

Suenaga

Lakaschus

2019

Proceedings of the 8th International Conference on Quarks and Nuclear Physics (QNP2018)

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We study mass modifications of scalar, pseudo-scalar, vector, and axial-vector mesons in nuclear matter comprehensively using the three-flavor extended Linear Sigma Model (eLSM) and the twoflavor Parity Doublet Model (PDM). Nuclear matter is constructed by the one-loop approximation of the nucleon together with the meson mean fields. Correspondingly, we include one-loop corrections by the nucleons as well as the meson mean fields to define the meson masses in medium. As a result, we find all spin-0 meson masses except the pion, kaon, and the lightest scalar-isoscalar ones decrease at finite baryon density. The mass reduction of the η meson in nuclear matter supports the possibility of the formation of η mesic nuclei. For spin-1 mesons, masses of all axial-vector mesons decrease in medium, whereas density dependences of ρ and ω meson masses sufficiently depend on the value of chiral invariant mass (M0). Also, our results suggest M0 ≈ 0.8 GeV is preferable.1 Other extensions of the Linear Sigma Model can be possible by including tetraquark states [35][36][37], for example.

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Asymmetric nuclear matter in a parity doublet model with hidden local symmetry

Cited by 75 publications

References 60 publications

Impact of the Nuclear Equation of State on the Stability of Hybrid Neutron Stars

Impact of the Nuclear Equation of State on the Stability of Hybrid Neutron Stars

Constraint to chiral invariant masses of nucleons from GW170817 in an extended parity doublet model

Mass Modifications of Light Mesons in Nuclear Matter with the Three Flavor Extended Linear Sigma Model

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