Extracting astrophysical information of highly eccentric binaries in the millihertz gravitational wave band
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1.
University of California, Los Angeles
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2.
California Institute of Technology
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3.
University of Oxford
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4.
University of British Columbia
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5.
University of California, San Diego
- 6. Flatiron Institute
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7.
Stony Brook University
Abstract
Wide, highly eccentric (𝑒 >0.9) compact binaries can naturally arise as progenitors of gravitational wave (GW) mergers. These systems are expected to have a significant population in the mHz band (e.g., ∼3–45 detectable stellar-mass binary black holes with 𝑒 >0.9 in the Milky Way), with their GW signals characterized by “repeated bursts” emitted upon each pericenter passage. In this study, we show that the detection of mHz GW signals from highly eccentric stellar mass binaries in the local universe can strongly constrain their orbital parameters. Specifically, it can achieve a relative measurement error of ∼10−6 for orbital frequency and ∼1% for eccentricity (as 1 −𝑒) in most of the detectable cases. On the other hand, the binary’s mass ratio, distance, and intrinsic orbital orientation may be less precisely determined due to degeneracies in the GW waveform. We also perform mock LISA data analysis to evaluate the realistic detectability of highly eccentric compact binaries. Our results show that highly eccentric systems could be efficiently identified when multiple GW sources and stationary Gaussian instrumental noise are present in the detector output. This work highlights the potential of extracting the signal of “bursting” LISA sources to provide valuable insights into their orbital evolution, surrounding environment, and formation channels.
Copyright and License
© 2025 American Physical Society.
Acknowledgement
The authors thank Aditya Vijaykumar for the valuable discussions and the anonymous referee for their useful comments. Z. X. acknowledges partial support from the Bhaumik Institute for Theoretical Physics summer fellowship. Z. X. and S. N. acknowledge the partial support from NASA ATP Grant No. 80NSSC20K0505 and from NSF-AST Grant No. 2206428 and thank Howard and Astrid Preston for their generous support. Further, Z. X. and S. N. thank LISA Sprint 2024 for organizing an interactive and productive meeting. J. M. acknowledges support from the Canada Research Chairs program. A. M. K. acknowledges funding support from a Killam Doctoral Scholarship. This work was supported by the Science and Technology Facilities Council Grant No. ST/W000903/1 (to B. K.).
Data Availability
No data were created or analyzed in this study.
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Additional details
- University of California, Los Angeles
- Bhaumik Institute for Theoretical Physics Summer Fellowship -
- National Aeronautics and Space Administration
- 80NSSC20K0505
- National Science Foundation
- AST-2206428
- Canada Research Chairs
- Killam Doctoral Scholarship
- Science and Technology Facilities Council
- ST/W000903/1
- Accepted
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2024-12-24Accepted
- Caltech groups
- LIGO
- Publication Status
- Published