Electron scale coherent structure as micro accelerator in the Earth’s magnetosheath

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作者
Zi-Kang Xie
Qiu-Gang Zong
Chao Yue
Xu-Zhi Zhou
Zhi-Yang Liu
Jian-Sen He
Yi-Xin Hao
Chung-Sang Ng
Hui Zhang
Shu-Tao Yao
Craig Pollock
Guan Le
Robert Ergun
Per-Arne Lindqvist
机构
[1] Peking University,Institute of Space Physics and Applied Technology
[2] Macau University of Science and Technology,State Key Laboratory of Lunar and Planetary Sciences
[3] Max Planck Institute for Solar System Research,Geophysical Institute
[4] University of Alaska Fairbanks,Shandong Provincial Key Laboratory of Optical Astronomy and Solar
[5] Shandong University,Terrestrial Environment, Institute of Space Sciences
[6] Denali Scientific,Department of Astrophysical and Planetary Sciences
[7] Heliophysics Science Division,Department of Space and Plasma Physics
[8] NASA,undefined
[9] Goddard Space Flight Center,undefined
[10] University of Colorado LASP,undefined
[11] KTH Royal Institute of Technology,undefined
来源
Nature Communications | / 15卷
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摘要
Turbulent energy dissipation is a fundamental process in plasma physics that has not been settled. It is generally believed that the turbulent energy is dissipated at electron scales leading to electron energization in magnetized plasmas. Here, we propose a micro accelerator which could transform electrons from isotropic distribution to trapped, and then to stream (Strahl) distribution. From the MMS observations of an electron-scale coherent structure in the dayside magnetosheath, we identify an electron flux enhancement region in this structure collocated with an increase of magnetic field strength, which is also closely associated with a non-zero parallel electric field. We propose a trapping model considering a field-aligned electric potential together with the mirror force. The results are consistent with the observed electron fluxes from ~50 eV to ~200 eV. It further demonstrates that bidirectional electron jets can be formed by the hourglass-like magnetic configuration of the structure.
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  • [1] Schekochihin AA(2009)Astrophysical gyrokinetics: kinetic and fluid turbulent cascades in magnetized weakly collisional plasmas Astrophys. J. Suppl. Ser. 182 310-143
  • [2] Brandenburg A(1996)Large-scale magnetic fields from hydromagnetic turbulence in the very early universe Phys. Rev. D 54 1291-542
  • [3] Enqvist K(2003)Nanosecond radio bursts from strong plasma turbulence in the Crab pulsar Nature 422 141-4709
  • [4] Olesen P(1996)Observation of turbulent fluctuations in the interstellar plasma density and magnetic field on spatial scales of 0.01 to 100 parsecs Astrophys. J. 458 194-775
  • [5] Hankins TH(2006)Anisotropic turbulent spectra in the terrestrial magnetosheath as seen by the Cluster spacecraft Phys. Rev. Lett. 96 075002-6917
  • [6] Kern JS(2011)Heating of the solar chromosphere and corona by Alfvén wave turbulence Astrophys. J. 736 3-982
  • [7] Weatherall JC(1999)The transport of cosmic rays across a turbulent magnetic field Astrophys. J. 520 204-1625
  • [8] Eilek JA(2011)Role of electron physics in the development of turbulent magnetic reconnection in collisionless plasmas Nat. Phys. 7 539-2057
  • [9] Minter AH(1970)Turbulent loss of ring current protons J. Geophys. Res. 75 4699-4940
  • [10] Spangler SR(1995)Toward a theory of interstellar turbulence. 2: strong alfvenic turbulence Astrophys. J. 438 763-21
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