Optically targeted search for gravitational waves emitted by core-collapse supernovae during the third observing run of Advanced LIGO and Advanced Virgo

Creators: Szczepańczyk, Marek J.¹; Zheng, Yanyan²; Antelis, Javier M.³; Benjamin, Michael; Bizouard, Marie-Anne⁴; Casallas-Lagos, Alejandro³; Cerdá-Durán, Pablo⁵; Davis, Derek⁶; Gondek-Rosińska, Dorota⁷; Klimenko, Sergey¹; Moreno, Claudia³; Obergaulinger, Martin⁵; Powell, Jade⁸; Ramirez, Dymetris³; Ratto, Brad³; Richardson, Colter⁹; Rijal, Abhinav³; Stuver, Amber L.¹⁰; Szewczyk, Paweł⁷; Vedovato, Gabriele¹¹; Zanolin, Michele³; Bartos, Imre¹; Bhaumik, Shubhagata¹; Bulik, Tomasz⁷; Drago, Marco¹²; Font, José A.⁵; De Colle, Fabio; García-Bellido, Juan¹³; Gayathri, V.¹⁴; Hughey, Brennan³; Mitselmakher, Guenakh¹; Mishra, Tanmaya¹; Mukherjee, Soma; Nguyen, Quynh Lan¹⁵; Chan, Man Leong¹⁶; Di Palma, Irene¹⁷; Piotrzkowski, Brandon J.¹⁴; Singh, Neha⁷

1. University of Florida
2. Missouri University of Science and Technology
3. Embry–Riddle Aeronautical University
4. Université Côte d'Azur
5. University of Valencia
6. California Institute of Technology
7. University of Warsaw
8. Swinburne University of Technology
9. University of Tennessee at Knoxville
10. Villanova University
11. University of Padua
12. INFN Sezione di Roma I
13. Institute for Theoretical Physics
14. University of Wisconsin–Milwaukee
15. University of Notre Dame
16. University of British Columbia
17. Sapienza University of Rome

Abstract

We present the results from a search for gravitational-wave transients associated with core-collapse supernovae observed optically within 30 Mpc during the third observing run of Advanced LIGO and Advanced Virgo. No gravitational wave associated with a core-collapse supernova has been identified. We then report the detection efficiency for a variety of possible gravitational-wave emissions. For neutrino-driven explosions, the distance at which we reach 50% detection efficiency is up to 8.9 kpc, while more energetic magnetorotationally driven explosions are detectable at larger distances. The distance reaches for selected models of the black hole formation, and quantum chromodynamics phase transition are also provided. We then constrain the core-collapse supernova engine across a wide frequency range from 50 Hz to 2 kHz. The upper limits on gravitational-wave energy and luminosity emission are at low frequencies down to 10−4⁢𝑀⊙⁢𝑐2 and 6×10−4⁢𝑀⊙⁢𝑐2/s, respectively. The upper limits on the proto-neutron star ellipticity are down to 3 at high frequencies. Finally, by combining the results obtained with the data from the first and second observing runs of LIGO and Virgo, we improve the constraints of the parameter spaces of the extreme emission models. Specifically, the proto-neutron star ellipticities for the long-lasting bar mode model are down to 1 for long emission (1 s) at high frequency.

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Acknowledgement

This document has been assigned LIGO Laboratory Document No. P2200361. This research has made use of data, software, and/or web tools obtained from the Gravitational Wave Open Science Center, a service of LIGO Laboratory, the LIGO Scientific Collaboration, and the Virgo Collaboration. This material is based upon work supported by NSF’s LIGO Laboratory which is a major facility fully funded by the National Science Foundation. The work by S. K. was supported by NSF Grant No. PHY 2110060. M. Z. was supported by NSF Grant No. PHY-1806885. M. C. and Y. Z. are partially supported by NSF Award No. PHY-2011334. A. S. is supported by NSF Grant No. PHY-2110157. J. P. is supported by the Australian Research Council (ARC) Discovery Early Career Researcher Award (DECRA) Project No. DE210101050 and the ARC Centre of Excellence for Gravitational Wave Discovery (OzGrav) Project No. CE170100004. Antelis and Moreno’s research is partially supported by CONACyT Ciencia de Frontera Project No. 376127. This work was partially supported by the Polish National Science Centre Grants No. 2017/26/M/ST9/00978, No. 2022/45/N/ST9/04115, and No. 2023/49/B/ST9/02777, POMOST/2012-6/11 Program of Foundation for Polish Science cofinanced by the European Union within the European Regional Development Fund. The project is co-financed by the Polish National Agency for Academic Exchange within Polish Returns Programme. P. C., J. F., and M. O. are supported by Grants No. PGC2018-095984-B-I00, No. PID2021-125485NB-C21, and No. PID2021-127495NB-I00 of the Spanish Agencia Estatal de Investigación and PROMETEO/2019/071 of the Generalitat Valenciana, all funded by the MCIN and the European Union. M. O. was supported by the Spanish Ramon y Cajal program (No. RYC-2018-024938-I). Q. L. N. was supported in part by the NSF Grant No. PHY-1748958. F. D. C. acknowledges support from the DGAPA/PAPIIT Grant No. 113424. The authors would like to thank the DLT40 and ASASSN teams for monitoring the sky for the purpose of this search. The authors would like to thank Noel Richardson for suggesting the Kepler light curves as testing ground for the CCSN light curve interpolations and Kiranjyot Gill for useful comments.

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