Plasmoid statistics in relativistic magnetic reconnection

Abstract

Plasmoids, quasi-spherical regions of plasma containing magnetic fields and high-energy particles, are a self-consistent by-product of the reconnection process in the relativistic regime. Recent two-dimensional particle-in-cell (PIC) simulations have shown that plasmoids can undergo a variety of processes (e.g. mergers, bulk acceleration, growth, and advection) within the reconnection layer. We developed a Monte Carlo (MC) code, benchmarked with the recent PIC simulations, to examine the effects of these processes on the steady-state size and momentum distributions of the plasmoid chain. The differential plasmoid size distribution is shown to be a power law, N(w) w-, ranging from a few plasma skin depths to 0.1 of the reconnection layer's length. We demonstrate numerically and analytically that the power law slope is linearly dependent upon the ratio of the plasmoid acceleration and growth rates and that it slightly decreases (from 2 to 1.3) with increasing plasma magnetization (from 3 to 50). We perform a detailed comparison of our results with those of recent PIC simulations and briefly discuss the astrophysical implications of our findings through the representative case of flaring events from blazar jets.