Abstract
Abstract We present new radio observations of the binary neutron star merger GW170817 carried out with the Karl G. Jansky Very large Array (VLA) more than 3 yr after the merger. Our combined data set is derived by coadding more than ≈32 hr of VLA time on-source, and as such provides the deepest combined observation (rms sensitivity ≈0.99 μJy) of the GW170817 field obtained to date at 3 GHz. We find no evidence for a late-time radio rebrightening at a mean epoch of t ≈ 1200 days since merger, in contrast to a ≈2.1σ excess observed at X-ray wavelengths at the same mean epoch. Our measurements agree with expectations from the post-peak decay of the radio afterglow of the GW170817 structured jet. Using these results, we constrain the parameter space of models that predict a late-time radio rebrightening possibly arising from the high-velocity tail of the GW170817 kilonova ejecta, which would dominate the radio and X-ray emission years after the merger (once the structured jet afterglow fades below detection level). Our results point to a steep energy-speed distribution of the kilonova ejecta (with energy-velocity power-law index α ≳ 5). We suggest possible implications of our radio analysis, when combined with the recent tentative evidence for a late-time rebrightening in the X-rays, and highlight the need for continued radio-to-X-ray monitoring to test different scenarios.
Highlights
GW170817 has been a milestone event for transient multimessenger studies
We have presented extensive late-time radio observations of the GW170817 field, carried out with the most extended configurations of the Very Large Array (VLA)
Our radio flux density measurements show that there is no evidence for emission in excess to the one expected from the afterglow of the GW170817 structured jet at 3 GHz and t ≈ 1200 days since merger
Summary
GW170817 has been a milestone event for transient multimessenger studies. It was the first binary neutron star (NS) merger observed by the LIGO and Virgo detectors (Abbott et al 2017), and so far it remains the only binary NS system from which gravitational waves (GWs) and a multiwavelength (radio to gamma-ray) counterpart have been discovered (Abbott et al 2020; Kasliwal et al 2020; Paterson et al 2021). Relatively shallow observations (rms ≈ 4.3 μJy) with the VLA at 3 GHz had reported a lack of radio detection contemporaneous with the X-ray late-time rebrightening (Alexander et al 2020). This radio nondetection was interpreted to be compatible with expectations from the simplest extrapolation of the X-ray excess to the radio band (Alexander et al 2020). We report our new observations in Section 2; in Section 3 we discuss our results within the kilonova afterglow model; in Section 4 we conclude with a summary
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