# On the properties of the massive binary black hole merger GW170729

**Authors:** Katerina Chatziioannou, Roberto Cotesta, Sudarshan Ghonge, Jacob, Lange, Ken K.-Y. Ng, Juan Calderon Bustillo, James Clark, Carl-Johan Haster,, Sebastian Khan, Michael Puerrer, Vivien Raymond, Salvatore Vitale, Nousha, Afshari, Stanislav Babak, Kevin Barkett, Jonathan Blackman, Alejandro Bohe,, Michael Boyle, Alessandra Buonanno, Manuela Campanelli, Gregorio Carullo,, Tony Chu, Eric Flynn, Heather Fong, Alyssa Garcia, Matthew Giesler, Maria, Haney, Mark Hannam, Ian Harry, James Healy, Daniel Hemberger, Ian Hinder,, Karan Jani, Bhavesh Khamersa, Lawrence E. Kidder, Prayush Kumar, Pablo, Laguna, Carlos O. Lousto, Geoffrey Lovelace, Tyson B. Littenberg, Lionel, London, Margaret Millhouse, Laura K. Nuttall, Frank Ohme, Richard, O'Shaughnessy, Serguei Ossokine, Francesco Pannarale, Patricia Schmidt,, Harald P. Pfeiffer, Mark A. Scheel, Lijing Shao, Deirdre Shoemaker, Bela, Szilagyi, Andrea Taracchini, Saul A. Teukolsky, Yosef Zlochower

arXiv: 1903.06742 · 2019-11-13

## TL;DR

This paper provides a detailed analysis of GW170729, revealing improved mass and spin estimates through advanced waveform models, and confirms the robustness of the results against systematic errors and alternative formation scenarios.

## Contribution

The study introduces improved waveform models with higher-order modes and compares different analysis methods, enhancing the understanding of GW170729's properties and formation history.

## Key findings

- Higher-order modes improve mass ratio estimates.
- Data is consistent with a smaller effective spin.
- Waveform models accurately describe the signal.

## Abstract

We present a detailed investigation into the properties of GW170729, the gravitational wave with the most massive and distant source confirmed to date. We employ an extensive set of waveform models, including new improved models that incorporate the effect of higher-order waveform modes which are particularly important for massive systems. We find no indication of spin-precession, but the inclusion of higher-order modes in the models results in an improved estimate for the mass ratio of $(0.3-0.8)$ at the 90\% credible level. Our updated measurement excludes equal masses at that level. We also find that models with higher-order modes lead to the data being more consistent with a smaller effective spin, with the probability that the effective spin is greater than zero being reduced from $99\%$ to $94\%$. The 90\% credible interval for the effective spin parameter is now $(-0.01-0.50)$. Additionally, the recovered signal-to-noise ratio increases by $\sim0.3$ units compared to analyses without higher-order modes. We study the effect of common spin priors on the derived spin and mass measurements, and observe small shifts in the spins, while the masses remain unaffected. We argue that our conclusions are robust against systematic errors in the waveform models. We also compare the above waveform-based analysis which employs compact-binary waveform models to a more flexible wavelet- and chirplet-based analysis. We find consistency between the two, with overlaps of $\sim 0.9$, typical of what is expected from simulations of signals similar to GW170729, confirming that the data are well-described by the existing waveform models. Finally, we study the possibility that the primary component of GW170729 was the remnant of a past merger of two black holes and find this scenario to be indistinguishable from the standard formation scenario.

## Full text

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## Figures

24 figures with captions in the complete paper: https://tomesphere.com/paper/1903.06742/full.md

## References

110 references — full list in the complete paper: https://tomesphere.com/paper/1903.06742/full.md

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Source: https://tomesphere.com/paper/1903.06742