Realistic finite-temperature effects in neutron star merger simulations
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PhysRevD.104.063016.pdf
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Affiliation
Department of Astronomy and Steward Observatory, University of ArizonaDepartment of Physics, University of Arizona
Issue Date
2021
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American Physical SocietyCitation
Raithel, C. A., Paschalidis, V., & Özel, F. (2021). Realistic finite-temperature effects in neutron star merger simulations. Physical Review D, 104(6).Journal
Physical Review DRights
Copyright © 2021 American Physical Society.Collection Information
This item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu.Abstract
Binary neutron star mergers provide a unique probe of the dense-matter equation of state (EoS) across a wide range of parameter space, from the zero-temperature EoS during the inspiral to the high-temperature EoS following the merger. In this paper, we implement a new model for calculating parametrized finite-temperature EoS effects into numerical relativity simulations. This "M∗-model"is based on a two-parameter approximation of the particle effective mass and includes the leading-order effects of degeneracy in the thermal pressure and energy. We test our numerical implementation by performing evolutions of rotating single stars with zero- and nonzero temperature gradients, as well as evolutions of binary neutron star mergers. We find that our new finite-temperature EoS implementation can support stable stars over many dynamical timescales. We also perform a first parameter study to explore the role of the M∗ parameters in binary neutron star merger simulations. All simulations start from identical initial data with identical cold EoSs, and differ only in the thermal part of the EoS. We find that both the thermal profile of the remnant and the postmerger gravitational wave signal depend on the choice of M∗ parameters, but that the total merger ejecta depends only weakly on the finite-temperature part of the EoS across a wide range of parameters. Our simulations provide a first step toward understanding how the finite-temperature properties of dense matter may affect future observations of binary neutron star mergers. © 2021 American Physical Society.Note
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2470-0010Version
Final published versionae974a485f413a2113503eed53cd6c53
10.1103/PhysRevD.104.063016