Low Lorentz Factor Jets from Compact Stellar Mergers - Candidate Electromagnetic Counterparts to Gravitational Wave Sources

Abstract

Short gamma-ray bursts (GRBs) are believed to be produced by relativistic jets from mergers of neutron-stars (NS) or neutron-stars and black-holes (BH). If the Lorentz-factors of jets from compact-stellar-mergers follow a similar power-law distribution to those observed for other high-energy astrophysical phenomena (e.g. blazars, AGN), the population of jets would be dominated by low- outflows. These jets will not produce the prompt gamma-rays, but jet energy will be released as x-ray/optical/radio transients when they collide with the ambient medium. Using Monte Carlo simulations, we study the properties of such transients. Approximately 78\% of merger-jets <300~Mpc result in failed-GRBs if the jet follows a power-law distribution of index -1.75. X-ray/optical transients from failed-GRBs will have broad distributions of their characteristics: light-curves peak tp0.1-10~days after a merger; flux peaks for x-ray 10-6~mJy~Fx10-2~mJy; and optical flux peaks at 14~mg22. X-ray transients are detectable by Swift XRT, and 85\% of optical transients will be detectable by telescopes with limiting magnitude mg 21, for well localized sources on the sky. X-ray/optical transients are followed by radio transients with peak times narrowly clustered around tp10~days, and peak flux of ~10-100~mJy at 10 GHz and ~0.1~mJy at 150 MHz. By considering the all-sky rate of short GRBs within the LIGO/Virgo range, the rate of on-axis orphan afterglows from failed-GRB would be 2.6(26) per year for NS-NS(NS-BH) mergers, respectively. Since merger jets from gravitational-wave (GW) trigger events tend to be directed to us, a significant fraction of GW events could be associated with the on-axis orphan afterglow.