Coherent curvature radiation and Fast Radio Bursts

TL;DR

This paper investigates coherent curvature radiation as the mechanism behind Fast Radio Bursts, analyzing parameter constraints, emission properties, and the implications for observed radio-only signals.

Contribution

It provides a detailed analysis of the conditions under which coherent curvature radiation can produce FRBs consistent with observations, including effects of self-absorption and magnetic geometry.

Findings

Self-absorption limits low-frequency luminosity.

Coherence favors steep optically thin spectra.

FRBs likely emit predominantly in radio frequencies with no strong counterparts.

Abstract

Fast radio bursts are extragalactic radio transient events lasting a few milliseconds with a ~Jy flux at ~1 GHz. We propose that these properties suggest a neutron star progenitor, and focus on coherent curvature radiation as the radiation mechanism. We study for which sets of parameters the emission can fulfil the observational constraints. Even if the emission is coherent, we find that self-absorption can limit the produced luminosities at low radio frequencies and that an efficient re-acceleration process is needed to balance the dramatic energy losses of the emitting particles. Self-absorption limits the luminosities at low radio frequency, while coherence favours steep optically thin spectra. Furthermore, the magnetic geometry must have a high degree of order to obtain coherent curvature emission. Particles emit photons along their velocity vectors, thereby greatly reducing the inverse Compton mechanism. In this case we predict that fast radio bursts emit most of their luminosities in the radio band and have no strong counterpart in any other frequency bands.