Synchrotron radiation from electrons with a pitch-angle distribution

Abstract

In most astrophysical processes involving synchrotron radiation, the pitch-angle distribution of the electrons is assumed to be isotropic. However, if electrons are accelerated anisotropically, e.g, in a relativistic shock wave with an ordered magnetic field or in magnetic reconnection regions, the electron pitch angles might be anisotropic. In this work, we study synchrotron radiation from electrons with a pitch-angle distribution with respect to a large-scale uniform magnetic field. Assuming that the pitch-angle distribution is normal with a scatter of σp and that the viewing direction is where the pitch-angle direction peaks, we find that for electrons with a Lorentz factor γ, the observed flux satisfies F2/3 for cr ( cr is the critical frequency of synchrotron), if σp1/γ is satisfied. On the other hand, if σp1/γ, the spectrum below cr is a broken power law with a break frequency br2 cr/σp3γ3, e.g., F2/3 for br and F1/3 for br cr. Thus the ultimate synchrotron line of death is F2/3. We discuss the application of this theory to blazars and gamma-ray bursts (GRBs).