An Electron-Scale Current Sheet Without Bursty Reconnection Signatures Observed in the Near-Earth Tail

被引：67

作者：

Wang, Rongsheng ^{[1
]}

Lu, Quanming ^{[1
]}

Nakamura, Rumi ^{[2
]}

Baumjohann, Wolfgang ^{[2
]}

Huang, Can ^{[1
]}

Russell, Christopher T. ^{[3
]}

Burch, J. L. ^{[4
]}

Pollock, Craig J. ^{[5
]}

Gershman, Dan ^{[5
]}

Ergun, R. E. ^{[6
]}

Wang, Shui ^{[1
]}

Lindqvist, P. A. ^{[7
]}

Giles, Barbara ^{[5
]}

机构：

[1] Univ Sci & Technol China, Dept Geophys & Planetary Sci, CAS Key Lab Geospace Environm, Hefei, Anhui, Peoples R China

[2] Austrian Acad Sci, Space Res Inst, Graz, Austria

[3] Univ Calif Los Angeles, Earth Planetary & Space Sci, Los Angeles, CA USA

[4] Southwest Res Inst, San Antonio, TX USA

[5] NASA, Goddard Space Flight Ctr, Greenbelt, MD USA

[6] Univ Colorado, Dept Astrophys & Planetary Sci, Boulder, CO 80309 USA

[7] Royal Inst Technol, Sch Elect Engn, Stockholm, Sweden

来源：

GEOPHYSICAL RESEARCH LETTERS | 2018年 / 45卷 / 10期

基金：

美国国家科学基金会; 奥地利科学基金会;

关键词：

magnetotail; current sheet; magnetic reconnection; THIN CURRENT SHEETS; MAGNETIC RECONNECTION; CLUSTER OBSERVATIONS; PLASMA SHEET; SOLAR-WIND; X-LINE; MAGNETOTAIL; MMS;

D O I：

10.1002/2017GL076330

中图分类号：

P [天文学、地球科学];

学科分类号：

07 ;

摘要：

Observations of a current sheet as thin as the electron scale are extremely rare in the near-Earth magnetotail. By measurement from the novel Magnetospheric Multiscale mission in the near-Earth magnetotail, we identified such an electron-scale current sheet and determined its detailed properties. The electron current sheet was bifurcated, with a half-thickness of nine electron inertial lengths, and was sandwiched between the Hall field. Because of the strong Hall electric field, the super-Alfvenic electron bulk flows were created mainly by the electric field drift, leading to the generation of the strong electron current. Inevitably, a bifurcated current sheet was formed since the Hall electric field was close to zero at the center of the current sheet. Inside the electron current sheet, the electrons were significantly heated while the ion temperature showed no change. The ions kept moving at a low speed, which was not affected by this electron current sheet. The energy dissipation was negligible inside the current sheet. The observations indicate that a thin current sheet, even as thin as electron scale, is not the sufficient condition for triggering bursty reconnection.

引用

页码：4542 / 4549

页数：8

共 50 条

[1] Electron currents supporting the near-Earth magnetotail during current sheet thinning [J].

Artemyev, A. V. ;

Angelopoulos, V. ;

Liu, J. ;

Runov, A. .

GEOPHYSICAL RESEARCH LETTERS, 2017, 44 (01) :5-11

[2] How typical are atypical current sheets? -: art. no. L03108 [J].

Asano, Y ;

Nakamura, R ;

Baumjohann, W ;

Runov, A ;

Vörös, Z ;

Volwerk, M ;

Zhang, TL ;

Balogh, A ;

Klecker, B ;

Réme, H .

GEOPHYSICAL RESEARCH LETTERS, 2005, 32 (03) :1-4

[3] Dynamics of thin current sheets: Cluster observations [J].

Baumjohann, W. ;

Roux, A. ;

Le Contel, O. ;

Nakamura, R. ;

Birn, J. ;

Hoshino, M. ;

Lui, A. T. Y. ;

Owen, C. J. ;

Sauvaud, J.-A. ;

Vaivads, A. ;

Fontaine, D. ;

Runov, A. .

ANNALES GEOPHYSICAE, 2007, 25 (06) :1365-1389

[4] Geospace Environment Modeling (GEM) magnetic reconnection challenge: Resistive tearing, anisotropic pressure and Hall effects [J].

Birn, J ;

Hesse, M .

JOURNAL OF GEOPHYSICAL RESEARCH-SPACE PHYSICS, 2001, 106 (A3) :3737-3750

[5] Electron-scale measurements of magnetic reconnection in space [J].

Burch, J. L. ;

Torbert, R. B. ;

Phan, T. D. ;

Chen, L. -J. ;

Moore, T. E. ;

Ergun, R. E. ;

Eastwood, J. P. ;

Gershman, D. J. ;

Cassak, P. A. ;

Argall, M. R. ;

Wang, S. ;

Hesse, M. ;

Pollock, C. J. ;

Giles, B. L. ;

Nakamura, R. ;

Mauk, B. H. ;

Fuselier, S. A. ;

Russell, C. T. ;

Strangeway, R. J. ;

Drake, J. F. ;

Shay, M. A. ;

Khotyaintsev, Yu. V. ;

Lindqvist, P. -A. ;

Marklund, G. ;

Wilder, F. D. ;

Young, D. T. ;

Torkar, K. ;

Goldstein, J. ;

Dorelli, J. C. ;

Avanov, L. A. ;

Oka, M. ;

Baker, D. N. ;

Jaynes, A. N. ;

Goodrich, K. A. ;

Cohen, I. J. ;

Turner, D. L. ;

Fennell, J. F. ;

Blake, J. B. ;

Clemmons, J. ;

Goldman, M. ;

Newman, D. ;

Petrinec, S. M. ;

Trattner, K. J. ;

Lavraud, B. ;

Reiff, P. H. ;

Baumjohann, W. ;

Magnes, W. ;

Steller, M. ;

Lewis, W. ;

Saito, Y. .

SCIENCE, 2016, 352 (6290)

[6] The Axial Double Probe and Fields Signal Processing for the MMS Mission [J].

Ergun, R. E. ;

Tucker, S. ;

Westfall, J. ;

Goodrich, K. A. ;

Malaspina, D. M. ;

Summers, D. ;

Wallace, J. ;

Karlsson, M. ;

Mack, J. ;

Brennan, N. ;

Pyke, B. ;

Withnell, P. ;

Torbert, R. ;

Macri, J. ;

Rau, D. ;

Dors, I. ;

Needell, J. ;

Lindqvist, P. -A. ;

Olsson, G. ;

Cully, C. M. .

SPACE SCIENCE REVIEWS, 2016, 199 (1-4) :167-188

[7]

Forslund D. W., 1968, THESIS

[8] The process of electron acceleration during collisionless magnetic reconnection [J].

Fu, XR ;

Lu, QM ;

Wang, S .

PHYSICS OF PLASMAS, 2006, 13 (01) :1-7

[9] New insights into dissipation in the electron layer during magnetic reconnection [J].

Ji, H. ;

Ren, Y. ;

Yamada, M. ;

Dorfman, S. ;

Daughton, W. ;

Gerhardt, S. P. .

GEOPHYSICAL RESEARCH LETTERS, 2008, 35 (13)

[10] Antiparallel versus component merging at the magnetopause: Current bifurcation and intermittent reconnection [J].

Karimabadi, H ;

Daughton, W ;

Quest, KB .

JOURNAL OF GEOPHYSICAL RESEARCH-SPACE PHYSICS, 2005, 110 (A3)

← 1 2 3 4 5 →