Gravitational-wave echoes from spinning exotic compact objects: Numerical waveforms from the Teukolsky equation
Abstract
We present numerical waveforms of gravitational-wave echoes from spinning exotic compact objects (ECOs) that result from binary black hole coalescence. We obtain these echoes by solving the Teukolsky equation for the ψ₄ associated with gravitational waves that propagate toward the horizon of a Kerr spacetime, and process the subsequent reflections of the horizon-going wave by the surface of the ECO, which lies right above the Kerr horizon. The trajectories of the infalling objects are modified from Kerr geodesics, such that the gravitational waves propagating toward future null infinity match those from merging black holes with comparable masses. In this way, the corresponding echoes can be used to approximate to those from nonspinning comparable-mass mergers. For boundary conditions at the ECO surface, we adopt recent work using the membrane paradigm, which relates ψ₀ associated with the horizon-going wave and ψ₄ of the wave that leaves the ECO surface. We obtain ψ₀ of the horizon-going wave from ψ₄ using the Teukolsky-Starobinsky relation. The echoes we obtain turn out to be significantly weaker than those from previous studies that generate echo waveforms by modeling the ringdown part of binary black hole coalescence waveforms as originating from the past horizon.
Additional Information
© 2021 American Physical Society. 0 Received 26 May 2021; accepted 3 October 2021; published 1 November 2021. Research of B. C. and Y. C. are supported by the Simons Foundation (Grant No. 568762), the Brinson Foundation, and the National Science Foundation (Grants No. PHY–2011968, No. PHY–2011961, and No. PHY–1836809). Research of S. X. and Q. W. was done in part during their visits to the California Institute of Technology, which was supported by funds from the Simons Foundation. R. K. L. L. and L. S. acknowledge support of the National Science Foundation and the LIGO Laboratory. LIGO was constructed by the California Institute of Technology and Massachusetts Institute of Technology with funding from the United States National Science Foundation, and operates under cooperative agreement No. PHY–1764464. Advanced LIGO was built under award No. PHY–0823459. R. K. L. L. would also like to acknowledge support from the Croucher Foundation. L. S. also acknowledges the support of the Australian Research Council Centre of Excellence for GW Discovery (OzGrav), project number CE170100004. W. H. is supported by CAS Project for Young Scientists in Basic Research YSBR-006, NSFC (National Natural Science Foundation of China) No. 11773059 and No. 12173071. The computations presented here were conducted on the Caltech High Performance Cluster partially supported by a grant from the Gordon and Betty Moore Foundation.Attached Files
Published - PhysRevD.104.104005.pdf
Accepted Version - 2105.12313.pdf
Files
| Name | Size | Download all |
|---|---|---|
|
md5:5bde669368e15ca5b20da4aa2ef25831
|
3.9 MB | Preview Download |
|
md5:9c5560b4d8ec1617524de02cdee1178f
|
4.2 MB | Preview Download |
Additional details
- Eprint ID
- 111917
- Resolver ID
- CaltechAUTHORS:20211117-164912749
- Simons Foundation
- 568762
- Brinson Foundation
- NSF
- PHY-2011968
- NSF
- PHY-2011961
- NSF
- PHY-1836809
- LIGO Laboratory
- NSF
- PHY-1764464
- NSF
- PHY-0823459
- Croucher Foundation
- Australian Research Council
- CE170100004
- Chinese Academy of Sciences
- YSBR-006
- National Natural Science Foundation of China
- 11773059
- National Natural Science Foundation of China
- 12173071
- Gordon and Betty Moore Foundation
- Created
-
2021-11-17Created from EPrint's datestamp field
- Updated
-
2021-11-17Created from EPrint's last_modified field
- Caltech groups
- LIGO, TAPIR, Walter Burke Institute for Theoretical Physics, Astronomy Department