Linear polarization in gamma-ray burst prompt emission

Abstract

Despite being hard to measure, GRB prompt γ-ray emission polarization is a valuable probe of the dominant emission mechanism and the outflow's composition and angular structure. During the prompt emission the outflow is ultra-relativistic with Lorentz factors 1. We describe in detail the linear polarization properties of various emission mechanisms: synchrotron radiation from different magnetic field structures (ordered: toroidal B tor or radial B, and random: normal to the radial direction B), Compton drag, and photospheric emission. We calculate the polarization for different GRB jet angular structures (e.g. top-hat, Gaussian, power-law) and viewing angles θ obs. Synchrotron with B can produce large polarizations, up to 25\%45\%, for a top-hat jet but only for lines of sight just outside the jet's sharp edge. The same also holds for Compton drag, albeit with a slightly higher overall . Moreover, we demonstrate how -variations during the GRB or smoother jet edges would significantly reduce . We construct a semi-analytic model for non-dissipative photospheric emission from structured jets. Such emission can produce up to 15\% with reasonably high fluences, but this requires steep gradients in (θ). A polarization of 50\%65\% can robustly be produced only by synchrotron emission from a transverse magnetic field ordered on angles \!1/ around our line of sight (like a global toroidal field). Therefore, such a model would be strongly favored even by a single secure measurement within this range. We find that such a model would also be favored if 20\% is measured in most GRBs within a large enough sample, by deriving the polarization distribution for our different emission and jet models.