Diffusion of relativistic charged particles and field lines in isotropic turbulence

Abstract: The transport of non-thermal particles across a large-scale magnetic field in the presence of magnetised turbulence has been a long-standing issue in high-energy astrophysics. Of particular interest is the dependence of the parallel and perpendicular mean free paths $\lambda_{\parallel}$ and $\lambda_{\perp}$ on rigidity $\mathcal{R}$. We have revisited this important issue with a view to applications from the transport of Galactic cosmic rays to acceleration at astrophysical shocks. We have run test particle simulations of cosmic ray transport in synthetic, isotropic Kolmogorov turbulence at unprecedentedly low reduced rigidites $r_g/L_c \simeq 10^{-4}$, corresponding to $\mathcal{R} \simeq 10 \, \text{TV}$ for a turbulent magnetic field of $B_{rms} = 4 \, \mu\text{G}$ and correlation length $L_c = 30 \, \text{pc}$. Extracting the (asymptotic) parallel and perpendicular mean free paths $\lambda_{\parallel}$ and $\lambda_{\perp}$, we have found $\lambda_{\parallel} \propto (r_g/L_c)^{1/3}$ as expected for a Kolmogorov turbulence spectrum. In contrast, $\lambda_{\perp}$ has a faster dependence on $r_g/L_c$ for $10^{-2} \lesssim r_g/L_c \lesssim 1$, but for $r_g/L_c \ll 10^{-2}$, also $\lambda_{\perp} \propto (r_g/L_c)^{1/3}$. Our results have important implications for the transport of Galactic cosmic rays.