Smooth equations of state for high-accuracy simulations of neutron star binaries
Abstract
High-accuracy numerical simulations of merging neutron stars play an important role in testing and calibrating the waveform models used by gravitational wave observatories. Obtaining high-accuracy waveforms at a reasonable computational cost, however, remains a significant challenge. One issue is that high-order convergence of the solution requires the use of smooth evolution variables, while many of the equations of state used to model the neutron star matter have discontinuities, typically in the first derivative of the pressure. Spectral formulations of the equation of state have been proposed as a potential solution to this problem. Here, we report on the numerical implementation of spectral equations of state in the spectral Einstein code. We show that, in our code, spectral equations of state allow for high-accuracy simulations at a lower computational cost than commonly used "piecewise polytrope" equations state. We also demonstrate that not all spectral equations of state are equally useful: different choices for the low-density part of the equation of state can significantly impact the cost and accuracy of simulations. As a result, simulations of neutron star mergers present us with a trade-off between the cost of simulations and the physical realism of the chosen equation of state.
Additional Information
© 2019 American Physical Society. Received 19 August 2019; published 25 November 2019. F. F. gratefully acknowledges support from the NSF through Grant No. PHY-1806278, and from NASA through Grant No. 80NSSC18K0565. M. D. gratefully acknowledges support from the NSF through Grant No. PHY-1806207. H. P. gratefully acknowledges support from the NSERC Canada. L. K. acknowledges support from NSF Grants No. PHY-1606654 and No. PHY-1912081. F. H. and M. S. acknowledge support from NSF Grants No. PHY-170212 and No. PHY-1708213. F. H., L. K. and M. S. also thank the Sherman Fairchild Foundation for their support. Resources supporting this work were provided by the NASA High-End Computing (HEC) Program through the NASA Advanced Supercomputing (NAS) Division at Ames Research Center (Grant No. HEC-SMD-17-1217). This research is also part of the Blue Waters sustained-petascale computing project, which is supported by the National Science Foundation (Awards No. OCI-0725070 and No. ACI-1238993) and the state of Illinois. Blue Waters is a joint effort of the University of Illinois at Urbana, Champaign, and its National Center for Supercomputing Applications. Computations were performed on Trillian, a Cray XE6m-200 supercomputer at UNH supported by the NSF MRI program under Grant No. PHY-1229408.Attached Files
Published - PhysRevD.100.104048.pdf
Submitted - 1908.05277.pdf
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Additional details
- Eprint ID
- 100042
- Resolver ID
- CaltechAUTHORS:20191125-142441489
- NSF
- PHY-1806278
- NASA
- 80NSSC18K0565
- NSF
- PHY-1806207
- Natural Sciences and Engineering Research Council of Canada (NSERC)
- NSF
- PHY-1606654
- NSF
- PHY-1912081
- NSF
- PHY-170212
- NSF
- PHY-1708213
- Sherman Fairchild Foundation
- NASA
- HEC-SMD-17-1217
- NSF
- OCI-0725070
- NSF
- ACI-1238993
- State of Illinois
- NSF
- PHY-1229408
- Created
-
2019-11-25Created from EPrint's datestamp field
- Updated
-
2021-11-16Created from EPrint's last_modified field
- Caltech groups
- TAPIR, Walter Burke Institute for Theoretical Physics