Two years of non-thermal emission from the binary neutron star merger GW170817: rapid fading of the jet afterglow and first constraints on the kilonova fastest ejecta

Abstract

We present Chandra and VLA observations of GW170817 at ~521-743 days post merger, and a homogeneous analysis of the entire Chandra data set. We find that the late-time non-thermal emission follows the expected evolution from an off-axis relativistic jet, with a steep temporal decay F t-1.950.15 and a simple power-law spectrum F -0.5750.007. We present a new method to constrain the merger environment density based on diffuse X-ray emission from hot plasma in the host galaxy and we find n 9.6 × 10-3\,cm-3. This measurement is independent from inferences based on the jet afterglow modeling and allows us to partially solve for model degeneracies. The updated best-fitting model parameters with this density constraint are a fireball kinetic energy E0 = 1.5-1.1+3.6× 1049\,erg (Eiso= 2.1-1.5+6.4×1052\, erg), jet opening angle θ0= 5.9+1.0-0.7\,deg with characteristic Lorentz factor j = 163-43+23, expanding in a low-density medium with n0 = 2.5-1.9+4.1 × 10-3\, cm-3 and viewed θobs = 30.4+4.0-3.4\, deg off-axis. The synchrotron emission originates from a power-law distribution of electrons with p=2.15+0.01-0.02. The shock microphysics parameters are constrained to εe = 0.18-0.13+0.30 and εB=2.3-2.2+16.0 × 10-3. We investigate the presence of X-ray flares and find no statistically significant evidence of 2.5σ of temporal variability at any time. Finally, we use our observations to constrain the properties of synchrotron emission from the deceleration of the fastest kilonova ejecta with energy EkKN (β)-α into the environment, finding that shallow stratification indexes α6 are disfavored.