Daniel A. Perley, Liverpool John Moores University
Anna Y.Q. Ho, Cornell University
Michael Fausnaugh, Texas Tech University
Gavin P. Lamb, Liverpool John Moores University
Mansi M. Kasliwal, California Institute of Technology
Tomas Ahumada, California Institute of Technology
Shreya Anand, California Institute of Technology
Igor Andreoni, NASA Goddard Space Flight Center
Eric Bellm, University of Washington
Varun Bhalerao, Indian Institute of Technology Bombay
Bryce Bolin, NASA Goddard Space Flight Center
Thomas G. Brink, University of California, Berkeley
Eric Burns, Louisiana State University
S. Bradley Cenko, NASA Goddard Space Flight Center
Alessandra Corsi, Texas Tech University
Alexei V. Filippenko, University of California, Berkeley
Dmitry Frederiks, Ioffe Institute
Adam Goldstein, Huntsville Program Office
Rachel Hamburg, Université Paris-Saclay
Rahul Jayaraman, MIT Kavli Institute for Astrophysics and Space Research
Peter G. Jonker, Radboud Universiteit
Erik C. Kool, Oskar Klein Centre
Shrinivas R. Kulkarni, California Institute of Technology
Harsh Kumar, Indian Institute of Technology Bombay
Russ Laher, Infrared Processing & Analysis Center
Andrew Levan, Radboud Universiteit
Alexandra Lysenko, Ioffe Institute
Richard A. Perley, National Radio Astronomy Observatory Socorro
George R. Ricker, MIT Kavli Institute for Astrophysics and Space Research
Reed Riddle, California Institute of Technology
Anna Ridnaia, Ioffe Institute
Ben Rusholme, Infrared Processing & Analysis Center
Roger Smith, California Institute of Technology

Document Type

Article

Publication Date

3-1-2025

Abstract

Classical gamma-ray bursts (GRBs) have two distinct emission episodes: prompt emission from ultrarelativistic ejecta and afterglow from shocked circumstellar material. While both components are extremely luminous in known GRBs, a variety of scenarios predict the existence of luminous afterglow emission with little or no associated high-energy prompt emission. We present AT 2019pim, the first spectroscopically confirmed afterglow with no observed high-energy emission to be identified. Serendipitously discovered during follow-up observations of a gravitational-wave trigger and located in a contemporaneous TESS sector, it is hallmarked by a fast-rising ( h), luminous ( mag) optical transient with accompanying luminous X-ray and radio emission. No gamma-ray emission consistent with the time and location of the transient was detected by Fermi-GBM or by Konus, placing constraining limits on an accompanying GRB. We investigate several independent observational aspects of the afterglow in the context of constraints on relativistic motion and find all of them are consistent with an initial Lorentz factor of 10-30 for the on-axis material, significantly lower than in any well-observed GRB and consistent with the theoretically predicted 'dirty fireball' scenario in which the high-energy prompt emission is stifled by pair production. However, we cannot rule out a structured jet model in which only the line-of-sight material was ejected at low-, off-axis from a classical high- jet core, and an on-axis GRB with below-average gamma-ray efficiency also remains a possibility. This event represents a milestone in orphan afterglow searches, demonstrating that luminous optical afterglows lacking detected GRB counterparts can be identified and spectroscopically confirmed in real time.

Publication Source (Journal or Book title)

Monthly Notices of the Royal Astronomical Society

First Page

1

Last Page

18

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