Relativistic mean-field models with scaled hadron masses and couplings: Hyperons and maximum neutron star mass

Maslov, Konstantin A.; Kolomeitsev, E. É.; Voskresensky, D. N.

doi:10.1016/j.nuclphysa.2016.03.011

Cited by 62 publications

(108 citation statements)

References 152 publications

Supporting

Mentioning

105

Contrasting

Unclassified

Order By: Relevance

“…Moreover, the rapid DU-like processes on the hyperons may occur. Although recently it was demonstrated [100,101] how these problems might be smoothened it would be important to include the hyperons in the cooling code.…”

Section: Resultsmentioning

confidence: 99%

Influence of the stiffness of the equation of state and in-medium effects on the cooling of compact stars

2016

View full text Add to dashboard Cite

Abstract. Measurements of the low masses for the pulsar PSR J0737-3039B, for the companion of PSR J1756-2251 and for the companion of PSR J0453+1559 on the one hand and of the high masses for the pulsars PSR J1614-2230 and PSR J0348-0432 on the other demonstrate the existence of compact stars with masses in a broad range from 1.2 to 2 M . The most massive of these objects might be hybrid stars. To fulfill the constraint Mmax > 2 M with a reserve we exploit the stiff DD2 hadronic equation of state (EoS) without and with excluded volume (DD2vex) correction, which produce maximum neutron star masses of Mmax = 2.43 M and 2.70 M , respectively. We show that the stiffness of the EoS does not preclude an explanation of the whole set of cooling data within "nuclear medium cooling" scenario for compact stars by a variation of the star masses. We select appropriate proton gap profiles from those exploited in the literature and allow for a variation of the effective pion gap controlling the efficiency of the medium modified Urca process. However, we suppress the possibility of pion condensation. In general, the stiffer the EoS the steeper a decrease with density of the effective pion gap is required. Results are compared with previously obtained ones for the HDD EoS for which Mmax = 2.06 M . The cooling of the compact star in the supernova remnant Cassiopeia A (Cas A) is explained mainly by an efficient medium modified Urca process. To explain a > ∼ 2.5% decline of the cooling curve for Cas A, as motivated by an analysis of the ACIS-S instrument data, together with other cooling data exploiting the DD2 EoS a large proton gap at densities n < ∼ 2n0 is required vanishing for n > ∼ 2.5 n0, where n0 is the saturation nuclear density. A smaller decline, as it follows from an analysis of the HRC-S instrument data, is explained with many choices of parameters. With the DD2vex EoS and using an effective pion gap steeper decreasing with the density and/or a proton gap shifted to smaller densities we are also able to reproduce both a strong decline compatible with ACIS-S data and HRC-S instrument data. The mass of Cas A is estimated as 1.6 − 1.9 M , above the value 1.5 M , which we have evaluated with the softer HDD equation of state. Different mass choices for the hottest object XMMU J173203.3-344518 are discussed. We make general remarks also on hybrid star cooling and on its dependence on the stiffness of the hadronic EoS.PACS. 97.60.Jd Neutron stars -95.30.Cq Elementary particle processes -26.60-c Nuclear matter aspects of neutron stars

show abstract

Section: Resultsmentioning

confidence: 99%

Influence of the stiffness of the equation of state and in-medium effects on the cooling of compact stars

2016

View full text Add to dashboard Cite

show abstract

“…For more details, see discussion in [1,[6][7][8][9][10][11][12][13][14]. Most difficult is the ability to satisfy simultaneously the heavy-ion-collision flow and the maximum neutron-star mass constraints.…”

Section: Existing Constraints On Eosmentioning

confidence: 99%

“…The problems were named the hyperon [15,16] and the ∆ [17,18] puzzles. These problems can be resolved in the RMF models with scaled hadron masses and couplings [9][10][11]14]. The model employed in [11,14] is a generalization of the NLW model with effective coupling constants g * mb = g mb χ mb (σ) and hadron masses m * i = m i Φ i (σ), which are functions of the σ field [8], i = {b, m}, where m = {σ, ω, ρ, φ} lists the included mesonic fields, b = {N, H, ∆} indicates a baryon (nucleon N = p, n; hyperon H = Λ, Σ, Ξ; and ∆ isobar).…”

Section: Hyperon and ∆-Isobar Puzzles And Their Resolution In Rmf Modmentioning

confidence: 99%

“…[9][10][11]14] use models of two kinds, the KVORcut-based models, where one exploits the cut in ω sector choosing accordingly the η ω ( f ) dependence, and the MKVORcut-based models, where one exploits the cut in ρ sector choosing accordingly the η ρ ( f ) dependence. In KVORcut models without inclusion of hyperons, the ρ − condensate appears by the second-order phase transition and the influence of the ρ − condensation on the EoS is minor.…”

Section: Hyperon and ∆-Isobar Puzzles And Their Resolution In Rmf Modmentioning

confidence: 99%

“…[10,46]. Calculation of the spin-parameters g = (g nn + g np )/2, g = (g nn − g np )/2 needs to incorporate the contribution in the NN interaction beyond the mean-field Hartree-level.…”

Section: Pions and Kaons In Dense Baryon Mattermentioning

confidence: 99%

See 2 more Smart Citations

On Manifestation of In-Medium Effects in Neutron Stars and Heavy-Ion Collisions

Voskresensky

2018

Universe

View full text Add to dashboard Cite

This review focuses on the demonstration of an interrelation between various in-medium effects, which are manifested in the phenomena occurring in neutron stars and heavy-ion collisions. More specifically, the equation of state of a baryon-rich cold hadron matter is considered. It is done within the relativistic mean-field approach with σ field-scaled hadron masses and couplings, and a cut-mechanism is discussed leading to an increase of the stiffness of the dense baryon matter. Then, I discuss the role of the viscosity and thermal conductivity in description of the first-order phase transitions occurring in heavy-ion collisions and neutron stars. Next, the p-wave polarization effects on pion and kaon spectra are studied beyond the mean-field level. In particular, the pion softening effect is detailed. Then, a role of in-medium effects in neutrino radiation of neutron stars is discussed and effects of the bulk and shear viscosities in the problem of r-mode damping in young rapidly rotating pulsars are considered.

show abstract

Studying the onset of deconfinement with multi‐messenger astronomy of neutron stars

Blaschke

Cierniak

2021

Astron Nachr

View full text Add to dashboard Cite

With the first multi‐messenger observation of a binary neutron star merger (GW170817), new constraints became available for masses and radii of neutron stars. We introduce a class of hybrid EoS that fulfills all these constraints and predicts a region in the mass‐radius diagram that could be populated only by hybrid neutron stars with quark matter cores. A confirmation of this conjecture would be provided when the NICER radius measurement for the high‐mass pulsar PSR J0740 + 6620 yields a radius significantly less than 11 km. Would this radius measurement yield a result in excess of 12 km, this would allow for both, a purely hadronic and a hybrid nature of this star. In the latter case, the maximum mass could reach 2.6 M⊙ so that the lighter object in the asymmetric binary merger GW190814 could have been a hybrid star. We demonstrate that this high mass can be compatible with an early onset of deconfinement for stars with masses below 1 M⊙ and the occurrence of low‐mass twin stars. In such a case, the remnant of GW170817 could be a long‐lived hypermassive pulsar.

show abstract

Relativistic mean-field models with scaled hadron masses and couplings: Hyperons and maximum neutron star mass

Cited by 62 publications

References 152 publications

Influence of the stiffness of the equation of state and in-medium effects on the cooling of compact stars

Influence of the stiffness of the equation of state and in-medium effects on the cooling of compact stars

On Manifestation of In-Medium Effects in Neutron Stars and Heavy-Ion Collisions

Studying the onset of deconfinement with multi‐messenger astronomy of neutron stars

Contact Info

Product

Resources

About