Energy Diffusion and Advection Coefficients in Kinetic Simulations of Relativistic Plasma Turbulence
Journal Article
Overview
abstract
Abstract; Turbulent, relativistic nonthermal plasmas are ubiquitous in high-energy astrophysical systems, as inferred from broadband nonthermal emission spectra. The underlying turbulent nonthermal particle acceleration (NTPA) processes have traditionally been modelled with a Fokker-Planck (FP) diffusion-advection equation for the particle energy distribution. We test FP-type NTPA theories by performing and analysing particle-in-cell (PIC) simulations of turbulence in collisionless relativistic pair plasma. By tracking large numbers of particles in simulations with different initial magnetisation and system size, we first test and confirm the applicability of the FP framework. We then measure the FP energy diffusion (D) and advection (A) coefficients as functions of particle energy γmc2, and compare their dependence to theoretical predictions. At high-energies, we robustly find D ∼ γ2 for all cases. Hence, we fit D = D0γ2 and find a scaling consistent with D0 ∼ σ3/2 at low instantaneous magnetisation σ(t), flattening to D0 ∼ σ at higher σ ∼ 1. We also find that the power-law index α(t) of the particle energy distribution converges exponentially in time. We build and test an analytic model connecting the FP coefficients and α(t), predicting A(γ) ∼ γlog γ. We confirm this functional form in our measurements of A(γ, t), which allows us to predict α(t) through the model relations. Our results suggest that the basic second-order Fermi acceleration model, which predicts D0 ∼ σ, may not be a complete description of NTPA in turbulent plasmas. These findings encourage further application of tracked particles and FP coefficients as a diagnostic in kinetic simulations of various astrophysically relevant plasma processes like collisionless shocks and magnetic reconnection.
