Abstract
Abstract. Recent studies of solar wind MHD turbulence show that current-sheet-like structures are common in the solar wind and they are a significant source of solar wind MHD turbulence intermittency. While numerical simulations have suggested that such structures can arise from non-linear interactions of MHD turbulence, a recent study by Borovsky (2006), upon analyzing one year worth of ACE data, suggests that these structures may represent the magnetic walls of flux tubes that separate solar wind plasma into distinct bundles and these flux tubes are relic structures originating from boundaries of supergranules on the surface of the Sun. In this work, we examine whether there are such structures in the Earth's magnetotail, an environment vastly different from the solar wind. We use high time resolution magnetic field data of the FGM instrument onboard Cluster C1 spacecraft. The orbits of Cluster traverse through both the solar wind and the Earth's magnetosheath and magnetotail. This makes its dataset ideal for studying differences between solar wind MHD turbulence and that inside the Earth's magnetosphere. For comparison, we also perform the same analysis when Cluster C1 is in the solar wind. Using a data analysis procedure first introduced in Li (2007, 2008), we find that current-sheet-like structures can be clearly identified in the solar wind. However, similar structures do not exist inside the Earth's magnetotail. This result can be naturally explained if these structures have a solar origin as proposed by Borovsky (2006). With such a scenario, current analysis of solar wind MHD turbulence needs to be improved to include the effects due to these curent-sheet-like structures.
Highlights
Solar wind provides us a great opportunity to study magnetohydrodynamic (MHD) turbulence in a collisionless plasma
To identify current sheets in the solar wind is the following: if there are magnetic walls separating plasma into individual flux tubes where the magnetic field directions change significantly between adjacent flux tubes, the quantity N ζ (θ
To better understand the origin of flux tubes in the solar wind, it is necessary that we examine plasmas that are different from solar wind
Summary
Solar wind provides us a great opportunity to study magnetohydrodynamic (MHD) turbulence in a collisionless plasma. Using a Haar wavelets technique, Veltri and Mangeney (1999) calculated power spectra and structure functions for a time range between 1 min to about 1 day Their results showed that in solar wind (a magneto-fluid) the most intermittent structures are current sheets where magnetic field rotates by an angle of about 120–130 degrees. To identify current sheets in the solar wind is the following: if there are magnetic walls separating plasma into individual flux tubes where the magnetic field directions change significantly between adjacent flux tubes, the quantity N ζ (θ
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