Kinetic turbulence in relativistic plasma: from thermal bath to non-thermal continuum

Abstract

We present results from particle-in-cell simulations of driven turbulence in magnetized, collisionless, and relativistic pair plasma. We find that fluctuations are consistent with the classical k-5/3 magnetic energy spectrum at fluid scales and a steeper k-4 spectrum at sub-Larmor scales, where k is the wavevector perpendicular to the mean field. We demonstrate the development of a non-thermal, power-law particle energy distribution, f(E) E-α, with index α that decreases with increasing magnetization and increases with increasing system size (relative to the characteristic Larmor radius). Our simulations indicate that turbulence can be a viable source of energetic particles in high-energy astrophysical systems, such as pulsar wind nebulae, if scalings asymptotically become insensitive to the system size.