Constraining the magnetic field structure in collisionless relativistic shocks with a radio afterglow polarization upper limit in GW170817

Abstract

Gamma-ray burst afterglows arise from relativistic collisionless shocks in which the postshock tangled magnetic field B is produced by the two-stream and/or Weibel instabilities on plasma skin-depth scales (c/ωp). The field is expected to be oriented predominantly within the shock plane (B; transverse to the shock normal, nsh), and is often approximated to be completely within it (Bnsh\,·\,B=0). Current 2D/3D particle-in-cell simulations are limited to short timescales and box sizes 104(c/ωp) R/sh much smaller than the shocked region's comoving width, and cannot probe the asymptotic downstream B structure. We constrain the latter using the linear polarization upper limit, ||<12\%, on the radio afterglow of GW170817/GRB170817A. Afterglow polarization depends on the jet's angular structure, our viewing angle, and the B structure. In GW170817/GRB170817A the latter can be tightly constrained since the former two are constrained from observations. We model B as an isotropic field in 3D that is stretched along nsh by a factor B/B, whose initial value fB,f/B,f describes the field that survives downstream on plasma scales R/sh. We calculate (f) by integrating over the shocked volume for core-dominated structured jets, with a local Blandford-McKee self-similar radial profile. We find that independent of the exact jet structure, B has a finite, but initially sub-dominant, parallel component: 0.57f0.89, making it less anisotropic. While this motivates numerical studies of the asymptotic B structure in relativistic collisionless shocks, it may be consistent with turbulence amplified magnetic field.