Observational quantification of three-dimensional anisotropies and scalings of space plasma turbulence at kinetic scales

Abstract

A statistical survey of spectral anisotropy of space plasma turbulence is performed using five years measurements from MMS in the magnetosheath. By measuring the five-point second-order structure functions of the magnetic field, we have for the first time quantified the three-dimensional anisotropies and scalings at sub-ion-scales (< 100 km). In the local reference frame ( L, l, l) defined with respect to local mean magnetic field B0 (Chen et al. 2012), the "statistical eddies" are found to be mostly elongated along B0 and shortened in the direction perpendicular to both B0 and local field fluctuations. From several di (ion inertial length) toward 0.05 di, the ratio between eddies' parallel and perpendicular lengths features a trend of rise then fall, whereas the anisotropy in the perpendicular plane appears scale-invariant. Specifically, the anisotropy relations for the total magnetic field at 0.1-1.0 di are obtained as l 2.44 · l0.71, and L 1.58 · l1.08, respectively. Our results provide new observational evidence to compare with phenomenological models and numerical simulations, which may help to better understand the nature of kinetic scale turbulence.