Faraday rotation in fast radio bursts
Abstract
Fast Radio Bursts (FBRs) show highly different polarization properties: high/small RMs, high/small circular/linear fractions. We outline a complicated picture of polarization propagation in the inner parts of the magnetars' winds, at scales few to hundreds of light cylinder radii. The key point is the Faraday rotation of linear polarization in highly magnetized symmetric pair plasma, a B2 effect. Position angle (PA) rotation rate is maximal for propagation across the magnetic field and disappears only for parallel propagation. In the highly magnetized regime, ω ωB, it becomes independent of the magnetic field. Very specific properties of PA(λ) (scaling of the rotation angle with the observed wavelength λ) can help identify/sort out the propagation effects. Two basic regimes in pair plasma predict PA λ and λ3 (depending on the magnetic dominance); both are different from the conventional plasma's PA = RM λ2. This is the main prediction of the model. A number of effects, all sensitive to the underlying parameters, contribute to the observed complicated polarization patterns: streaming of plasma along magnetic field lines near the light cylinder, Faraday depolarization, effects of limiting polarization, the associated effect of linear-circular conversion, and synchrotron absorption.
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