Isospin equilibration in neutron star mergers

Mark G. Alford; Alexander Haber; Ziyuan Zhang

doi:10.1103/PhysRevC.109.055803

Isospin equilibration in neutron star mergers

Mark G. Alford
, Alexander Haber
, Ziyuan Zhang

Department of Physics

Research output: Contribution to journal › Article › peer-review

12 Scopus citations

Abstract

We analyze the isospin equilibration properties of neutrinoless nuclear (npe) matter in the temperature and density range that is relevant to neutron star mergers. Our analysis incorporates neutrino-transparency corrections to the isospin ("beta") equilibrium condition which become noticeable at T≳1MeV. We find that the isospin relaxation rate rises rapidly as temperature rises, and at T≈5MeV it is comparable to the timescale of the density oscillations that occur immediately after the merger. This produces a resonant peak in the bulk viscosity at T≈5MeV, which causes density oscillations to be damped on the timescale of the merger. Our calculations suggest that isospin relaxation dynamics may also be relevant when neutrinos are treated more accurately via neutrino transport schemes.

Original language	English
Article number	055803
Journal	Physical Review C
Volume	109
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevC.109.055803
State	Published - May 2024

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10.1103/PhysRevC.109.055803

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title = "Isospin equilibration in neutron star mergers",

abstract = "We analyze the isospin equilibration properties of neutrinoless nuclear (npe) matter in the temperature and density range that is relevant to neutron star mergers. Our analysis incorporates neutrino-transparency corrections to the isospin ({"}beta{"}) equilibrium condition which become noticeable at T≳1MeV. We find that the isospin relaxation rate rises rapidly as temperature rises, and at T≈5MeV it is comparable to the timescale of the density oscillations that occur immediately after the merger. This produces a resonant peak in the bulk viscosity at T≈5MeV, which causes density oscillations to be damped on the timescale of the merger. Our calculations suggest that isospin relaxation dynamics may also be relevant when neutrinos are treated more accurately via neutrino transport schemes.",

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AU - Haber, Alexander

AU - Zhang, Ziyuan

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N2 - We analyze the isospin equilibration properties of neutrinoless nuclear (npe) matter in the temperature and density range that is relevant to neutron star mergers. Our analysis incorporates neutrino-transparency corrections to the isospin ("beta") equilibrium condition which become noticeable at T≳1MeV. We find that the isospin relaxation rate rises rapidly as temperature rises, and at T≈5MeV it is comparable to the timescale of the density oscillations that occur immediately after the merger. This produces a resonant peak in the bulk viscosity at T≈5MeV, which causes density oscillations to be damped on the timescale of the merger. Our calculations suggest that isospin relaxation dynamics may also be relevant when neutrinos are treated more accurately via neutrino transport schemes.

AB - We analyze the isospin equilibration properties of neutrinoless nuclear (npe) matter in the temperature and density range that is relevant to neutron star mergers. Our analysis incorporates neutrino-transparency corrections to the isospin ("beta") equilibrium condition which become noticeable at T≳1MeV. We find that the isospin relaxation rate rises rapidly as temperature rises, and at T≈5MeV it is comparable to the timescale of the density oscillations that occur immediately after the merger. This produces a resonant peak in the bulk viscosity at T≈5MeV, which causes density oscillations to be damped on the timescale of the merger. Our calculations suggest that isospin relaxation dynamics may also be relevant when neutrinos are treated more accurately via neutrino transport schemes.

UR - https://www.scopus.com/pages/publications/85192749007

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SN - 2469-9985

VL - 109

JO - Physical Review C

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Isospin equilibration in neutron star mergers

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