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1. Neutron–Mirror-Neutron Oscillation and Neutron Star Cooling

   https://doi.org/10.1103/PhysRevLett.129.061103  

   Goldman, Itzhak; Mohapatra, Rabindra N.; Nussinov, Shmuel; Zhang, Yongchao (August 2022, Physical Review Letters)
2. Inferring Small Neutron Star Spins with Neutron Star–Black Hole Mergers

   https://doi.org/10.3847/1538-4357/ad49a0  

   Gupta, Ish (July 2024, The Astrophysical Journal)

   Abstract The precise measurement of neutron star (NS) spins can provide important insight into the formation and evolution of compact binaries containing NSs. While traditional methods of NS spin measurement rely on pulsar observations, gravitational-wave detections offer a complementary avenue. However, determining component spins with gravitational waves is hindered by the small dimensionless spins of the NSs and the degeneracy in the mass and spin parameters. This degeneracy can be addressed by the inclusion of higher-order modes in the waveform, which are important for systems with unequal masses. This study shows the suitability of NS–black hole mergers, which are naturally mass-asymmetric, for precise NS spin measurements. We explore the effects of the black hole masses and spins, higher-mode content, inclination angles, and detector sensitivity on the measurement of NS spin. We find that networks with next-generation observatories like the Cosmic Explorer and the Einstein Telescope can distinguish NS dimensionless spin of 0.04 (0.1) from zero at 1σconfidence for events within ∼350 (∼1000) Mpc. Networks with A+ and A^♯detectors achieve similar distinction within ∼30 (∼70) Mpc and ∼50 (∼110) Mpc, respectively. 

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3. Gravitational waveforms from spectral Einstein code simulations: Neutron star-neutron star and low-mass black hole-neutron star binaries

   https://doi.org/10.1103/PhysRevD.99.044008  

   Foucart, F.; Duez, M. D.; Hinderer, T.; Caro, J.; Williamson, Andrew R.; Boyle, M.; Buonanno, A.; Haas, R.; Hemberger, D. A.; Kidder, L. E.; et al (February 2019, Physical Review D)
4. Proto-Neutron Star Matter

   https://doi.org/10.1088/1742-6596/2340/1/012013  

   Alp, A; Farrell, D; Weber, F; Malfatti, G; Orsaria, M G; Ranea-Sandoval, I F (September 2022, Journal of Physics: Conference Series)

   Abstract In this paper, we explore the properties of proto-neutron star matter. The relativistic finite-temperature Green function formalism is used to derive the equations which determine the properties of such matter. The calculations are performed for the relativistic non-linear mean-filed theory, where different combinations of lepton number and entropy have been investigated. All particles of the baryon octet as well as all electrically charged states of the Δ isobar have been included in the calculations. The presence of all these particles is shown to be extremely temperature (entropy) dependent, which should have important consequences for the evolution of proto-neutron stars to neutron stars as well as the behavior of neutron stars in compact star mergers. 

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5. Neutron-Star-Merger Equation of State

   https://doi.org/10.3390/universe5050129  

   Dexheimer, Veronica; Constantinou, Constantinos; Most, Elias R.; Papenfort, L. Jens; Hanauske, Matthias; Schramm, Stefan; Stoecker, Horst; Rezzolla, Luciano (May 2019, Universe)

   null (Ed.)

   In this work, we discuss the dense matter equation of state (EOS) for the extreme range of conditions encountered in neutron stars and their mergers. The calculation of the properties of such an EOS involves modeling different degrees of freedom (such as nuclei, nucleons, hyperons, and quarks), taking into account different symmetries, and including finite density and temperature effects in a thermodynamically consistent manner. We begin by addressing subnuclear matter consisting of nucleons and a small admixture of light nuclei in the context of the excluded volume approach. We then turn our attention to supranuclear homogeneous matter as described by the Chiral Mean Field (CMF) formalism. Finally, we present results from realistic neutron-star-merger simulations performed using the CMF model that predict signatures for deconfinement to quark matter in gravitational wave signals. 

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