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On the electron diffusion region in asymmetric reconnection with a guide magnetic field
Author(s) -
Hesse Michael,
Liu YiHsin,
Chen LiJen,
Bessho Naoki,
Kuznetsova Masha,
Birn Joachim,
Burch James L.
Publication year - 2016
Publication title -
geophysical research letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.007
H-Index - 273
eISSN - 1944-8007
pISSN - 0094-8276
DOI - 10.1002/2016gl068373
Subject(s) - stagnation point , physics , magnetic field , magnetic reconnection , electron , diffusion , magnetohydrodynamics , gyroradius , pressure gradient , magnetic pressure , field (mathematics) , plane (geometry) , condensed matter physics , computational physics , mechanics , geometry , magnetization , quantum mechanics , heat transfer , mathematics , pure mathematics
Particle‐in‐cell simulations in a 2.5‐D geometry and analytical theory are employed to study the electron diffusion region in asymmetric reconnection with a guide magnetic field. The analysis presented here demonstrates that similar to the case without guide field, in‐plane flow stagnation and null of the in‐plane magnetic field are well separated. In addition, it is shown that the electric field at the local magnetic X point is again dominated by inertial effects, whereas it remains dominated by nongyrotropic pressure effects at the in‐plane flow stagnation point. A comparison between local electron Larmor radii and the magnetic gradient scale lengths predicts that distribution should become nongyrotropic in a region enveloping both field reversal and flow stagnation points. This prediction is verified by an analysis of modeled electron distributions, which show clear evidence of mixing in the critical region.