Radio precursors of monster shocks: a mechanism for fast radio bursts from SGR 1935+2154

Abstract

Kilohertz perturbations in active magnetars evolve into monster radiative shocks at radii r 108 cm. The shock generates X-rays and a semi-coherent radio precursor, which strongly interacts with the magnetospheric plasma ahead of the shock. We show that this interaction self-regulates the precursor emission and find its self-consistent frequency and luminosity. The precursor frequency falls in the GHz band and its production peaks when the shock expands to r≈ 109 cm. The resulting GHz burst has a sub-millisecond duration and energy E FRB≈ 1034 E380.2 erg where E is the energy of the primary magnetosonic disturbance that launched the shock. As the GHz burst propagates to the light cylinder R LC 1010 cm, it faces a threat of being absorbed by the magnetosphere. The burst escapes if the local plasma density at R LC is 30 times lower than typically expected for active magnetars, so distant observers need some luck to see the radio burst. The shock X-rays follow the radio waves with a millisecond delay. Shocks from kilohertz disturbances with energies E 1038 erg generate X-ray and radio bursts similar to the activity detected in SGR 1935+2154.