Efficient Electron Acceleration Driven by Flux Rope Evolution during Turbulent Reconnection

Magnetic flux ropes or magnetic islands are important structures responsible for electron acceleration and energy conversion during turbulent reconnection. However, the evolution of flux ropes and the corresponding electron acceleration process still remain open questions. In this paper, we present a comparative study of flux ropes observed by the Magnetospheric Multiscale mission in the outflow region during an example of turbulent reconnection in Earth's magnetotail. Interestingly, we find the farther the flux rope is away from the X-line, the bigger the size of the flux rope and the slower it moves. We estimate the power density converted at the observed flux ropes via the three fundamental electron acceleration mechanisms: Fermi, betatron, and parallel electric field. The dominant acceleration mechanism at all three flux ropes is the betatron mechanism. The flux rope that is closest to the X-line, having the smallest size and the fastest moving velocity, is the most efficient in accelerating electrons. Significant energy also returns from particles to fields around the flux ropes, which may facilitate the turbulence in the reconnection outflow region.

[1]  Y. Liu,et al.  The Effect of Current on Magnetic Null Topology during Turbulent Reconnection , 2022, The Astrophysical Journal.

[2]  A. Vaivads,et al.  Monitoring the Spatio-temporal Evolution of a Reconnection X-line in Space , 2020, The Astrophysical Journal.

[3]  Xiaocan Li,et al.  Exploring the Acceleration Mechanisms for Particle Injection and Power-law Formation during Transrelativistic Magnetic Reconnection , 2020, The Astrophysical Journal.

[4]  E. Grigorenko,et al.  Magnetotail dipolarization fronts and particle acceleration: A review , 2019, Science China Earth Sciences.

[5]  Xiaocan Li,et al.  Energetic Electron Acceleration in Unconfined Reconnection Jets , 2019, The Astrophysical Journal.

[6]  M. Velli,et al.  Turbulence and Particle Acceleration in Collisionless Magnetic Reconnection: Effects of Temperature Inhomogeneity across Pre-reconnection Current Sheet , 2019, The Astrophysical Journal.

[7]  Y. Liu,et al.  Parallel Electron Heating by Tangential Discontinuity in the Turbulent Magnetosheath , 2019, The Astrophysical Journal.

[8]  G. Zank,et al.  Particle Acceleration at 5 au Associated with Turbulence and Small-scale Magnetic Flux Ropes , 2019, The Astrophysical Journal.

[9]  A. Vaivads,et al.  Super-efficient Electron Acceleration by an Isolated Magnetic Reconnection , 2019, The Astrophysical Journal.

[10]  G. Zank,et al.  An Unusual Energetic Particle Flux Enhancement Associated with Solar Wind Magnetic Island Dynamics , 2018, The Astrophysical Journal.

[11]  Shengtai Li,et al.  Large-scale Compression Acceleration during Magnetic Reconnection in a Low-β Plasma , 2018, The Astrophysical Journal.

[12]  Q. Lu,et al.  Formation of power law spectra of energetic electrons during multiple X line magnetic reconnection with a guide field , 2018, Physics of Plasmas.

[13]  H. Fu,et al.  Electron Acceleration by Dipolarization Fronts and Magnetic Reconnection: A Quantitative Comparison , 2018 .

[14]  Xiaocan Li,et al.  The Roles of Fluid Compression and Shear in Electron Energization during Magnetic Reconnection , 2018, 1801.02255.

[15]  M. Dunlop,et al.  Magnetic Nulls in the Reconnection Driven by Turbulence , 2017 .

[16]  U. Gliese,et al.  Fast Plasma Investigation for Magnetospheric Multiscale , 2016 .

[17]  J. B. Blake,et al.  Electron-scale measurements of magnetic reconnection in space , 2016, Science.

[18]  Thomas E. Moore,et al.  Magnetospheric Multiscale Overview and Science Objectives , 2016 .

[19]  Wolfgang Baumjohann,et al.  The Magnetospheric Multiscale Magnetometers , 2016 .

[20]  Per-Arne Lindqvist,et al.  The Axial Double Probe and Fields Signal Processing for the MMS Mission , 2016 .

[21]  T. Nguyen,et al.  The Fly’s Eye Energetic Particle Spectrometer (FEEPS) Sensors for the Magnetospheric Multiscale (MMS) Mission , 2016 .

[22]  M. R. Stokes,et al.  The Energetic Particle Detector (EPD) Investigation and the Energetic Ion Spectrometer (EIS) for the Magnetospheric Multiscale (MMS) Mission , 2016 .

[23]  P. Lindqvist,et al.  The Spin-Plane Double Probe Electric Field Instrument for MMS , 2016 .

[24]  Wolfgang Baumjohann,et al.  The FIELDS Instrument Suite on MMS: Scientific Objectives, Measurements, and Data Products , 2016 .

[25]  R. Nakamura,et al.  Coalescence of magnetic flux ropes in the ion diffusion region of magnetic reconnection , 2015, Nature Physics.

[26]  H. Ji,et al.  Conversion of magnetic energy in the magnetic reconnection layer of a laboratory plasma , 2014, Nature Communications.

[27]  J. Drake,et al.  The mechanisms of electron heating and acceleration during magnetic reconnection , 2014, 1406.0831.

[28]  A. Vaivads,et al.  Energetic electron acceleration by unsteady magnetic reconnection , 2013, Nature Physics.

[29]  A. Runov,et al.  Electron fluxes and pitch‐angle distributions at dipolarization fronts: THEMIS multipoint observations , 2013 .

[30]  William Daughton,et al.  Large-scale electron acceleration by parallel electric fields during magnetic reconnection , 2011, Nature Physics.

[31]  William Daughton,et al.  Role of electron physics in the development of turbulent magnetic reconnection in collisionless plasmas , 2011 .

[32]  I. J. Rae,et al.  Tail Reconnection Triggering Substorm Onset , 2008, Science.

[33]  Shinsuke Imada,et al.  Observation of energetic electrons within magnetic islands , 2008 .

[34]  C. Owen,et al.  In situ evidence of magnetic reconnection in turbulent plasma , 2007 .

[35]  M. Shay,et al.  Electron acceleration from contracting magnetic islands during reconnection , 2006, Nature.

[36]  Quanming Lu,et al.  The process of electron acceleration during collisionless magnetic reconnection , 2006 .

[37]  J. Birn,et al.  Electron acceleration in the dynamic magnetotail: Test particle orbits in three-dimensional magnetohydrodynamic simulation fields , 2004 .

[38]  M. Shimojo,et al.  Hot-Plasma Ejections Associated with Compact-Loop Solar Flares , 1995 .