Delineating the properties of matter in cold, dense QCD

Kojo, Toru

doi:10.1063/1.5117813

Cited by 7 publications

(3 citation statements)

References 96 publications

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“…The first-order phase transition leaves a marked imprint on the macroscopic properties of compact stars because the EoS contains a density jump, which may give rise to new stable branches of compact stars (i.e., their third family) separated from nucleonic stars by a region of instability [34][35][36][37]. Smooth crossover without changes in the values of the order parameter or the wave function of the three-quark states would be a less dramatic change in the slope of the EoS, best visualized in terms of the speed of sound [10,22,38]. As mentioned above, two sequential first-order phase transitions can lead to the appearance of a new branch of compact stars-fourth family-separated from the third family by an instability region [15,33,39,40], assuming the classical stability criterion dM/dρ c > 0 is valid.…”

Section: A Brief Review Of the Phase Diagram Of Dense Qcdmentioning

confidence: 99%

Impact of Multiple Phase Transitions in Dense QCD on Compact Stars

Sedrakian

2023

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This review covers several recent developments in the physics of dense QCD with an emphasis on the impact of multiple phase transitions on astrophysical manifestations of compact stars. To motivate the multi-phase modeling of dense QCD and delineate the perspectives, we start with a discussion of the structure of its phase diagram and the arrangement of possible color-superconducting and other phases. It is conjectured that pair-correlated quark matter in β-equilibrium is within the same universality class as spin-imbalanced cold atoms and the isospin asymmetrical nucleonic matter. This then implies the emergence of phases with broken space symmetries and tri-critical (Lifshitz) points. The beyond-mean-field structure of the quark propagator and its non-trivial implications are discussed in the cases of two- and three-flavor quark matter within the Eliashberg theory, which takes into account the frequency dependence (retardation) of the gap function. We then construct an equation of state (EoS) that extends the two-phase EoS of dense quark matter within the constant speed of sound parameterization by adding a conformal fluid with a speed of sound cconf.=1/3 at densities ≥10nsat, where nsat is the saturation density. With this input, we construct static, spherically symmetrical compact hybrid stars in the mass–radius diagram, recover such features as the twins and triplets, and show that the transition to conformal fluid leads to the spiraling-in of the tracks in this diagram. Stars on the spirals are classically unstable with respect to the radial oscillations but can be stabilized if the conversion timescale between quark and nucleonic phases at their interface is larger than the oscillation period. Finally, we review the impact of a transition from high-temperature gapped to low-temperature gapless two-flavor phase on the thermal evolution of hybrid stars.

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Section: A Brief Review Of the Phase Diagram Of Dense Qcdmentioning

confidence: 99%

Impact of Multiple Phase Transitions in Dense QCD on Compact Stars

Sedrakian

2023

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“…More microscopic arguments were proposed in [110] based on the quarkyonic matter hypothesis [111] in which high-density matter has the quark Fermi sea but baryonic Fermi surface. Baryons on top of the Fermi sea may be regarded as relativistic baryons with three quarks collectively moving in the same direction, unlike baryons at low density where the moving directions of three quarks are opposite one another, leaving a small baryon momentum (and pressure) but a large mass density [112]. Changes from the non-relativistic to relativistic regime may be a microscopic origin of phenomenological repulsion used in hadronic models.…”

Section: Speed Of Soundmentioning

confidence: 99%

QCD equations of state and speed of sound in neutron stars

Kojo

2021

AAPPS Bull.

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Neutron stars are cosmic laboratories to study dense matter in quantum chromodynamics (QCD). The observable mass-radius relations of neutron stars are determined by QCD equations of state and can reflect the properties of QCD phase transitions. In the last decade, there have been historical discoveries in neutron stars; the discoveries of two-solar mass neutron stars and neutron star merger events, which have imposed tight constraints on equations of state. While a number of equations of state are constructed to satisfy these constraints, a theoretical challenge is how to reconcile those constructions with the microphysics expected from the hadron physics and in-medium calculations. In this short article, we briefly go over recent observations and discuss their implications for dense QCD matter, referring to QCD constraints in the low- and high-density limits, QCD-like theories, and lattice QCD results for baryon-baryon interactions.

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“…One of the key observables in neutron star physics is mass-radius sequence of neutron stars (M -R relation), which has a one-to-one correspondence with the underlying equation of state (EOS). The shape of the M -R curve is correlated with the stiffness of EOS at several fiducial densities [6]. The low density part (n B 2n 0 ) is largely correlated with the overall radii of neutron stars while the high density part (n B 3-5n 0 ) determines the maximum mass.…”

Section: Introduction Imentioning

confidence: 98%

Chiral condensates for neutron stars in hadron-quark crossover; from a parity doublet nucleon model to an NJL quark model

Takuya

Kojo²,

Harada³

2022

Supl. Rev. Mex. Fis.

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In this contribution, we summarize our recent studies on the chiral invariant mass and the chiral condensates in neutron star matter. We construct a unified equations of state assuming the crossover phase transition from hadronic matter described by a parity doublet model to quark matter by an Nambu--Jona-Lasinio type quark model. We first show that the chiral invariant mass is constrained to be $600\,\mbox{MeV}\, \lesssim\, m_0 \,\lesssim \, 900\,\mbox{MeV}$ from recent observations of neutron stars. We then determine the density dependence of the chiral condensate in the crossover description, and show that the chiral condensates are actually smoothly connected from the hadronic matter where the change is driven by the positive chiral scalar charge in a nucleon, to the quark matter where the change is by the modification of the quark Dirac sea, reflecting the hadron-quark crossover.

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Delineating the properties of matter in cold, dense QCD

Cited by 7 publications

References 96 publications

Impact of Multiple Phase Transitions in Dense QCD on Compact Stars

Impact of Multiple Phase Transitions in Dense QCD on Compact Stars

QCD equations of state and speed of sound in neutron stars

Chiral condensates for neutron stars in hadron-quark crossover; from a parity doublet nucleon model to an NJL quark model

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