Accuracy of gravitational waveform models for observing neutron-star–black-hole binaries in Advanced LIGO
Abstract
Gravitational waves radiated by the coalescence of compact-object binaries containing a neutron star and a black hole are one of the most interesting sources for the ground-based gravitational-wave observatories Advanced LIGO and Advanced Virgo. Advanced LIGO will be sensitive to the inspiral of a 1.4M⊙ neutron star into a 10M⊙ black hole to a maximum distance of ∼900 Mpc. Achieving this sensitivity and extracting the physics imprinted in observed signals requires accurate modeling of the binary to construct template waveforms. In a neutron-star–black-hole binary, the black hole may have significant angular momentum (spin), which affects the phase evolution of the emitted gravitational waves. We investigate the ability of currently available post-Newtonian templates to model the gravitational waves emitted during the inspiral phase of neutron-star–black-hole binaries. We restrict to the case where the spin of the black hole is aligned with the orbital angular momentum and compare several post-Newtonian approximants. We examine restricted amplitude post-Newtonian waveforms that are accurate to third-and-a-half post-Newtonian order in the orbital dynamics and complete to second-and-a-half post-Newtonian order in the spin dynamics. We also consider post-Newtonian waveforms that include the recently derived third-and-a-half post-Newtonian order spin-orbit correction and the third post-Newtonian order spin-orbit tail correction. We compare these post-Newtonian approximants to the effective-one-body waveforms for spin-aligned binaries. For all of these waveform families, we find that there is a large disagreement between different waveform approximants, starting at low to moderate black hole spins, particularly for binaries where the spin is antialigned with the orbital angular momentum. The match between the TaylorT4 and TaylorF2 approximants is ∼0.8 for a binary with m_BH/m_NS∼4 and χ_BH = cJ_BH/Gm^(2)_(BH)∼0.4. We show that the divergence between the gravitational waveforms begins in the early inspiral at v∼0.2 for χ_BH∼0.4. Post-Newtonian spin corrections beyond those currently known will be required for optimal detection searches and to measure the parameters of neutron-star–black-hole binaries. The strong dependence of the gravitational-wave signal on the spin dynamics will make it possible to extract significant astrophysical information from detected systems with Advanced LIGO and Advanced Virgo.
Additional Information
© 2013 American Physical Society. Received 6 July 2013; published 26 December 2013. We thank Stefan Ballmer, Alessandra Buonanno, Eliu Huerta, Prayush Kumar, Richard O'Shaughnessy, B. S. Sathyaprakash, Peter Saulson, and Matt West for useful discussions. This work is supported by National Science Foundation Awards No. PHY-0847611 (DAB, AHN), No. PHY-1205835 (AHN, IWH), No. PHY-0970074 (EO), and No. PHY-0855589 (AL). D. A. B., I.W. H., A. L., and E. O. thank the Kavli Institute for Theoretical Physics at Santa Barbara University, supported in part by NSF Grant No. PHY-0551164, for hospitality during this work. D. A. B. thanks the LIGO Laboratory Visitors Program, supported by NSF cooperative agreement No. PHY-0757058, for hospitality. D. K. and A.L. thank the Max Planck Gesellschaft for support. D.A.B. is supported by a Cottrell Scholar award from the Research Corporation for Science Advancement. Computations used in this work were performed on the Syracuse University Gravitation and Relativity cluster, which is supported by NSF Awards No. PHY-1040231 and No. PHY-1104371.Attached Files
Published - PhysRevD.88.124039.pdf
Submitted - 1307.1757v1.pdf
Files
Name | Size | Download all |
---|---|---|
md5:9272bc3ca04b0c4669e96924b94ec347
|
7.4 MB | Preview Download |
md5:d569458a7f462180cd4e807929127533
|
12.7 MB | Preview Download |
Additional details
- Eprint ID
- 44599
- Resolver ID
- CaltechAUTHORS:20140402-093450958
- PHY-0847611
- NSF
- PHY-1205835
- NSF
- PHY-0970074
- NSF
- PHY-0855589
- NSF
- PHY-0551164
- NSF
- PHY-0757058
- NSF Cooperative Agreement
- Max Planck Gesellschaft
- Research Corporation for Science Advancement Cottrell Scholar award
- PHY-1040231
- NSF
- PHY-1104371
- NSF
- Created
-
2014-04-02Created from EPrint's datestamp field
- Updated
-
2021-11-10Created from EPrint's last_modified field