Evolution of the Earth's Magnetosheath Turbulence: A statistical study based on MMS observations

Abstract

Composed of shocked solar wind, the Earth's magnetosheath serves as a natural laboratory to study the transition of turbulence from low Alfv\'en Mach number, MA, to high MA. The simultaneous observations of magnetic field and plasma moments with unprecedented high temporal resolution provided by NASA's Magnetospheric Multiscale Mission enable us to study the magnetosheath turbulence at both magnetohydrodynamics (MHD) and sub-ion scales. Based on 1841 burst-mode segments of MMS-1 from 2015/09 to 2019/06, comprehensive patterns of the spatial evolution of magnetosheath turbulences are obtained: (1) from the sub-solar region to the flanks, MA increases from < 1 to > 5. At MHD scales, the spectral indices of the magnetic-field and velocity spectra present a positive and negative correlation with MA. However, no obvious correlations between the spectral indices and MA are found at sub-ion scales. (2) from the bow shock to the magnetopause, the turbulent sonic Mach number, Mturb, generally decreases from > 0.4 to < 0.1. All spectra steepen at MHD scales and flatten at sub-ion scales, representing a positive/negative correlations with Mturb. The break frequency increases by 0.1 Hz when approaching the magnetopause for the magnetic-field and velocity spectra, while it remains at 0.3 Hz for the density spectra. (3) In spite of some differences, similar results are found for the quasi-parallel and quasi-perpendicular magnetosheath. In addition, the spatial evolution of magnetosheath turbulence is found to be independent of the upstream solar wind conditions, e.g., the Z-component of the interplanetary magnetic field and the solar wind speed.