Periastron advance in spinning black hole binaries: Gravitational self-force from numerical relativity
Abstract
We study the general relativistic periastron advance in spinning black hole binaries on quasicircular orbits, with spins aligned or antialigned with the orbital angular momentum, using numerical-relativity simulations, the post-Newtonian approximation, and black hole perturbation theory. By imposing a symmetry by exchange of the bodies' labels, we devise an improved version of the perturbative result and use it as the leading term of a new type of expansion in powers of the symmetric mass ratio. This allows us to measure, for the first time, the gravitational self-force effect on the periastron advance of a nonspinning particle orbiting a Kerr black hole of mass M and spin S=−0.5M^2, down to separations of order 9M. Comparing the predictions of our improved perturbative expansion with the exact results from numerical simulations of equal-mass and equal-spin binaries, we find a remarkable agreement over a wide range of spins and orbital separations.
Additional Information
© 2013 American Physical Society. Received 2 September 2013; published 9 December 2013. A. B. and A. L. T. acknowledge support from NSF through Grants No. PHY-0903631 and No. PHY-1208881. A. B. also acknowledges support from NASA through Grant No. NNX09AI81G and A. L. T. from the Maryland Center for Fundamental Physics. A. M. and H. P. acknowledge support from NSERC of Canada, from the Canada Research Chairs Program, and from the Canadian Institute for Advanced Research. D. H., L. K., G. L., and S. T. acknowledge support from the Sherman Fairchild Foundation and NSF Grants No. PHY-1306125 and No. PHYS-1005426 at Cornell. M. S., B. S., and N. T. gratefully acknowledge support from the Sherman Fairchild Foundation and NSF Grants No. PHY-1068881, No. PHY-1005655, and No. DMS-1065438 at Caltech. The numerical relativity simulations were performed at the GPC supercomputer at the SciNet HPC Consortium [65]; SciNet is funded by the Canada Foundation for Innovation (CFI) under the auspices of Compute Canada; the Government of Ontario; Ontario Research Fund–Research Excellence; and the University of Toronto. Further computations were performed on the Caltech computer cluster Zwicky, which was funded by the Sherman Fairchild Foundation and the NSF MRI-R2 Grant No. PHY- 0960291, on SHC at Caltech, which is supported by the Sherman Fairchild Foundation, and on the NSF XSEDE network under Grant No. TG-PHY990007N.Attached Files
Published - PhysRevD.88.124027.pdf
Submitted - 1309.0541v2.pdf
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Additional details
- Eprint ID
- 43401
- Resolver ID
- CaltechAUTHORS:20140116-093422080
- PHY-0903631
- NSF
- PHY-1208881
- NSF
- NNX09AI81G
- NASA
- NSERC (Canada)
- Canada Research Chairs Program
- Canadian Institute for Advanced Research
- Sherman Fairchild Foundation
- PHY-1306125
- NSF
- PHYS-1005426
- NSF
- PHY-1068881
- NSF
- PHY-1005655
- NSF
- DMS-1065438
- NSF
- Maryland Center for Fundamental Physics
- PHY-0960291
- NSF MRI-R2
- TG-PHY990007N
- NSF XSEDE
- Canada Foundation for Innovation (CFI)
- Government of Ontario
- Ontario Research Fund-Research Excellence
- University of Toronto
- Compute Canada
- Created
-
2014-01-16Created from EPrint's datestamp field
- Updated
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2021-11-10Created from EPrint's last_modified field