Lowly polarized light from a highly magnetized jet of GRB 190114C

Abstract

We report multi-color optical imaging and polarimetry observations of the afterglow of the first TeV- detected gamma-ray burst, GRB 190114C, using RINGO3 and MASTER II polarimeters. Observations begin 31 s after the onset of the GRB and continue until 7000\,s post-burst. The light curves reveal a chromatic break at 400- 500\,s, with initial temporal decay α = 1.669 0.013 flattening to α 1 post-break, which we model as a combination of reverse and forward-shock components, with magnetization parameter R B 70. The observed polarization degree decreases from 7.7 1.1\% to 2-4\% during 52-109\,s post-burst and remains steady at this level for the subsequent 2000-s, at constant position angle. Broadband spectral energy distribution modeling of the afterglow confirms GRB 190114C is highly obscured (A v, HG = 1.49 0.12 \,mag; N H, HG= (9.0 0.3) × 1022\,cm-2). We interpret the measured afterglow polarization as intrinsically low and dominated by dust, in contrast to P >10\% measured previously for other GRB reverse shocks, with a small contribution from polarized prompt photons in the first minute. We test whether 1st and higher-order inverse Compton scattering in a magnetized reverse shock can explain the low optical polarization and the sub-TeV emission but conclude neither is explained in the reverse shock Inverse Compton model. Instead, the unexpectedly low intrinsic polarization degree in GRB 190114C can be explained if large-scale jet magnetic fields are distorted on timescales prior to reverse shock emission.