Abstract
Abstract We present the Dark Energy Camera (DECam) discovery of the optical counterpart of the first binary neutron star merger detected through gravitational-wave emission, GW170817. Our observations commenced 10.5 hr post-merger, as soon as the localization region became accessible from Chile. We imaged 70 deg2 in the i and z bands, covering 93% of the initial integrated localization probability, to a depth necessary to identify likely optical counterparts (e.g., a kilonova). At 11.4 hr post-merger we detected a bright optical transient located from the nucleus of NGC 4993 at redshift z = 0.0098, consistent (for km s−1 Mpc−1) with the distance of 40 ± 8 Mpc reported by the LIGO Scientific Collaboration and the Virgo Collaboration (LVC). At detection the transient had magnitudes of and , and thus an absolute magnitude of , in the luminosity range expected for a kilonova. We identified 1500 potential transient candidates. Applying simple selection criteria aimed at rejecting background events such as supernovae, we find the transient associated with NGC 4993 as the only remaining plausible counterpart, and reject chance coincidence at the 99.5% confidence level. We therefore conclude that the optical counterpart we have identified near NGC 4993 is associated with GW170817. This discovery ushers in the era of multi-messenger astronomy with gravitational waves and demonstrates the power of DECam to identify the optical counterparts of gravitational-wave sources.
Highlights
The joint detection of electromagnetic (EM) and gravitational-wave (GW) emission from astrophysical sources is one of the holy grails of present-day astronomy
We find that the probability of a chance coincidence is ∼0.5%, and we conclude that our optical transient is associated with GW170817
We report the Dark Energy Camera (DECam) discovery of the optical counterpart to the BNS merger GW170817, an object with i = 17.30 mag and z = 17.43 mag at 11.40 hr post-merger
Summary
The joint detection of electromagnetic (EM) and gravitational-wave (GW) emission from astrophysical sources is one of the holy grails of present-day astronomy. 01:15:01UT (Allam et al 2017), including a reference to a GCN from the 1M2H Collaboration at 01:05:23 UT (SSS17a; Coulter et al 2017), and subsequent to our GCN the DLT40 team announced an independent detection (DLT17ck; Yang et al 2017 reported at 01:41:13 UT); see LIGO Scientific Collaboration & Virgo Collaboration et al (2017a) for an overview of the observations carried out by the community. This transient has received an IAU name of AT2017gfo. A measurement of the Hubble constant, the first utilizing a gravitational-wave event as a standard siren measurement of distance (Schutz 1986; Dalal et al 2006), is enabled by this work and is described in LIGO Scientific Collaboration & Virgo Collaboration et al (2017b)
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