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

   Goldman, Itzhak; Mohapatra, Rabindra N.; Nussinov, Shmuel; Zhang, Yongchao (August 2022, Physical Review Letters)
2. From neutron skins and neutron matter to the neutron star crust

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   Newton, William G.; Preston, Rebecca; Balliet, Lauren; Ross, Michael (November 2022, Physics Letters B)
3. Internal consistency of neutron coherent scattering length measurements from neutron interferometry and from neutron gravity reflectometry

   https://doi.org/10.1103/PhysRevD.101.062004  

   Snow, W. M.; Apanavicius, J.; Dickerson, K. A.; Devaney, J. S.; Drabek, H.; Reid, A.; Shen, B.; Woo, J.; Haddock, C.; Alexeev, E.; et al (March 2020, Physical Review D)
4. The Impact of Neutron Transfer Reactions on the Heating and Cooling of Accreted Neutron Star Crusts

   https://doi.org/10.3847/1538-4357/ac4271  

   Schatz, H.; Meisel, Z.; Brown, E. F.; Gupta, S. S.; Hitt, G. W.; Hix, W. R.; Jain, R.; Lau, R.; Möller, P.; Ong, W. -J.; et al (February 2022, The Astrophysical Journal)

   Abstract Nuclear reactions heat and cool the crust of accreting neutron stars and need to be understood to interpret observations of X-ray bursts and long-term cooling in transiently accreting systems. It was recently suggested that previously ignored neutron transfer reactions may play a significant role in the nuclear processes. We present results from full nuclear network calculations that now include these reactions and determine their impact on crust composition, crust impurity, heating, and cooling. We find that a large number of neutron transfer reactions indeed occur and impact crust models. In particular, we identify a new type of reaction cycle that brings a pair of nuclei across the nuclear chart into equilibrium via alternating neutron capture and neutron release, interspersed with a neutron transfer. While neutron transfer reactions lead to changes in crust model predictions and need to be considered in future studies, previous conclusions concerning heating, cooling, and compositional evolution are remarkably robust. 

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5. Angular-momentum Transport in Proto-neutron Stars and the Fate of Neutron Star Merger Remnants

   https://doi.org/10.3847/1538-4357/ac8b01  

   Margalit, Ben; Jermyn, Adam S.; Metzger, Brian D.; Roberts, Luke F.; Quataert, Eliot (November 2022, The Astrophysical Journal)

   Abstract Both the core collapse of rotating massive stars, and the coalescence of neutron star (NS) binaries result in the formation of a hot, differentially rotating NS remnant. The timescales over which differential rotation is removed by internal angular-momentum transport processes (viscosity) have key implications for the remnant’s long-term stability and the NS equation of state (EOS). Guided by a nonrotating model of a cooling proto-NS, we estimate the dominant sources of viscosity using an externally imposed angular-velocity profile Ω(r). Although the magneto-rotational instability provides the dominant source of effective viscosity at large radii, convection and/or the Tayler–Spruit dynamo dominate in the core of merger remnants wheredΩ/dr≥ 0. Furthermore, the viscous timescale in the remnant core is sufficiently short that solid-body rotation will be enforced faster than matter is accreted from rotationally supported outer layers. Guided by these results, we develop a toy model for how the merger remnant core grows in mass and angular momentum due to accretion. We find that merger remnants with sufficiently massive and slowly rotating initial cores may collapse to black holes via envelope accretion, even when the total remnant mass is less than the usually considered threshold ≈1.2M_TOVfor forming a stable solid-body rotating NS remnant (whereM_TOVis the maximum nonrotating NS mass supported by the EOS). This qualitatively new picture of the post-merger remnant evolution and stability criterion has important implications for the expected electromagnetic counterparts from binary NS mergers and for multimessenger constraints on the NS EOS. 

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