Thermal evolution of hybrid stars within the framework of a nonlocal Nambu–Jona-Lasinio model

Carvalho, Sheyse Martins de; Negreiros, Rodrigo; Orsaria, M.; Contrera, Gustavo A.; Weber, Fridolin; Spinella, William M.

doi:10.1103/physrevc.92.035810

Cited by 25 publications

(18 citation statements)

References 70 publications

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“…It has been shown that vector interaction contributions in the description of quark matter plays a crucial role in the description of massive hybrid stars in agreement with observational data [25,59,76,92,[133][134][135][136][137][138]. These contributions have been investigated for different quark models [135,137,138]), and applied to neutron stars studies [59,76,[134][135][136].…”

Section: B Quark Phasementioning

confidence: 91%

Constraining Strangeness in Dense Matter with GW170817

Gomes

Char

Schramm

2019

ApJ

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Particles with strangeness content are predicted to populate dense matter, modifying the equation of state of matter inside neutron stars as well as their structure and evolution. In this work, we show how the modeling of strangeness content in dense matter affects the properties of isolated neutrons stars and the tidal deformation in binary systems. For describing nucleonic and hyperonic stars we use the many-body forces model (MBF) at zero temperature, including the φ mesons for the description of repulsive hyperon-hyperon interactions. Hybrid stars are modeled using the MIT Bag Model with vector interaction (vMIT) in both Gibbs and Maxwell constructions, for different values of bag constant and vector interaction couplings. A parametrization with a Maxwell construction, which gives rise to third family of compact stars (twin stars), is also investigated. We calculate the tidal contribution that adds to the post-Newtonian point-particle corrections, the associated love number for sequences of stars of different composition (nucleonic, hyperonic, hybrid and twin stars), and determine signatures of the phase transition on the gravitational waves in the accumulated phase correction during the inspirals among different scenarios for binary systems. On the light of the recent results from GW170817 and the implications for the radius of ∼ 1.4 M⊙ stars, our results show that hybrid stars can only exist if a phase transition takes place at low densities close to saturation.

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Section: B Quark Phasementioning

confidence: 91%

Constraining Strangeness in Dense Matter with GW170817

Gomes

Char

Schramm

2019

ApJ

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“…The first aspect of our strategy is to use a conservative model of cooling which is not contaminated by the uncertainties in the rates of rapid neutrino emission processes, which in turn strongly depend on the composition of dense matter at densities above the saturation of nuclear matter. Modern simulations of cooling of neutron stars (see, for example, the work by different groups on hadronic models [38][39][40][41][42][43] and hybrid star models [44][45][46][47]) demonstrate that fast neutrino processes do not operate in low-mass neutron stars with M ≤ 1.5M ⊙ because each such process is associated with a certain density threshold (which need not be sharp, see in particular Refs. [40,41] for this type of modeling).…”

Section: Introductionmentioning

confidence: 99%

Axion cooling of neutron stars

2016

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Cooling simulations of neutron stars and their comparison with the data from thermally emitting x-ray sources put constraints on the properties of axions, and by extension of any light pseudoscalar dark matter particles, whose existence has been postulated to solve the strong-CP problem of QCD. We incorporate the axion emission by pair-breaking and formation processes by S-and P -wave nucleonic condensates in a benchmark code for cooling simulations as well as provide fit formulas for the rates of these processes. Axion cooling of neutron stars has been simulated for 24 models covering the mass range 1 to 1.8 solar masses, featuring nonaccreted iron and accreted light-element envelopes, and a range of nucleon-axion couplings. The models are based on an equation state predicting conservative physics of superdense nuclear matter that does not allow for the onset of fast cooling processes induced by phase transitions to non-nucleonic forms of matter or high proton concentration. The cooling tracks in the temperature vs age plane were confronted with the (timeaveraged) measured surface temperature of the central compact object in the Cas A supernova remnant as well as surface temperatures of three nearby middle-aged thermally emitting pulsars.We find that the axion coupling is limited to fa/10 7 GeV ≥ (5-10), which translates into an upper bound on axion mass ma ≤ (0.06-0.12) eV for Peccei-Quinn charges of the neutron |Cn| ∼ 0.04 and proton |Cp| ∼ 0.4 characteristic for hadronic models of axions.

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“…For that purpose we consider the thermal evolution of these objects, by making use of state of the art cooling calculations [62][63][64]. We employ the most recent thermal emission and cooling mechanisms available, that have also been used to explain the thermal properties of the cooling neutron star in Cassiopeia A [62,[65][66][67].…”

Section: Evolution Aspectsmentioning

confidence: 99%

Many Aspects of Magnetic Fields in Neutron Stars

et al. 2018

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Abstract:In this work, we explore different aspects in which strong magnetic fields play a role in the composition, structure and evolution of neutron stars. More specifically, we discuss (i) how strong magnetic fields change the equation of state of dense matter, alter its composition, and create anisotropies, (ii) how they change the structure of neutron stars (such mass and radius) and the formalism necessary to calculate those changes, and (iii) how they can affect neutron stars' evolution. In particular, we focus on how a time-dependent magnetic field modifies the cooling of a special group known as X-ray dim neutron stars.

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Thermal evolution of hybrid stars within the framework of a nonlocal Nambu–Jona-Lasinio model

Cited by 25 publications

References 70 publications

Constraining Strangeness in Dense Matter with GW170817

Constraining Strangeness in Dense Matter with GW170817

Axion cooling of neutron stars

Many Aspects of Magnetic Fields in Neutron Stars

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