Slow shock characteristics as a function of distance from the X‐line in the magnetotail

Lee, L. C.; Lin, Y.; Shi, Y.; Tsurutani, B. T.

doi:10.1029/gl016i008p00903

Cited by 33 publications

(30 citation statements)

References 23 publications

(15 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A series of MHD discontinuities can be generated by magnetic reconnection. [2][3][4][5][6] Observations of slow shocks in the solar wind have been reported by Chao and Olbert, 7 Feldman et al, 8 and Saito et al 9 In hybrid simulations of slow shock, leakage of downstream heated ions to the upstream leads to an anisotropy pressure in the foreshock region, [10][11][12][13][14] in which the local intermediate-mode speed is highly reduced. Rotational discontinuities have been observed in the solar wind.…”

Section: Introductionmentioning

confidence: 90%

“…Previous studies have also shown that the tail lobe-plasma sheet boundary in the mid-and distant tail often behaves as a quasi-perpendicular slow shock, which may be due to the Petschek-type reconnection occurring in the tail. 8,9,12,14,[24][25][26][27][28][29][30][31][32][33] However, with a statistical survey from Geotail and Wind data, Whang et al 22 argued that occurrence of DDs in the tail lobe-plasma sheet boundary is no less than the stand-along slow shocks, which implies that the DDs are easy to be generated in the geomagnetic tail.…”

Section: Introductionmentioning

confidence: 96%

See 1 more Smart Citation

Generation of shock/discontinuity compound structures through magnetic reconnection in the geomagnetic tail

et al. 2012

Self Cite

View full text Add to dashboard Cite

We use 1-D hybrid code to simulate the generation and evolution of MHD discontinuities associated with magnetic reconnection in a current sheet. It is found that the leakage of slow shock (SS) downstream particles to upstream region tends to increase the ion parallel temperature and temperature anisotropy with b ijj =b i? ) 1, where b ijj ðb i? Þ is the ion parallel (perpendicular) beta. As a result, the propagation speed of rotational discontinuity (RD) is highly reduced and RD becomes attached to SS, leading to formation of various compound structures in the reconnection outflow region. Four types of compound structure are found in our simulations: (a) RD-SS compound structure: the RD is attached to the leading part of SS, (b) SS-RD (DD) compound structure: RD is attached to the rear part of SS, (c) SS-RD-SS compound structure: RD is trapped inside SS, and (d) switch-off slow shock (SSS) with a rotational wave train. The type of compound structure generated depends on initial ion beta b i0 and magnetic shear angle /. RD tends to move in front of SS to form an RD-SS compound structure for cases with low b i0 . RD stays behind SS and form an SS-RD (DD) compound structure for large b i0 . The SS-RD-SS compound structure is formed for intermediate values of b i0 . When the shear angle is 180 , SSS with a wave train is formed.

show abstract

Section: Introductionmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 96%

Generation of shock/discontinuity compound structures through magnetic reconnection in the geomagnetic tail

et al. 2012

Self Cite

View full text Add to dashboard Cite

show abstract

“…However, observations in the geomagnetic tail (on board the ISEE-3 rocket) failed to detect the presence of such waves. To eliminate the inconsistency between theoretical predictions and observations, researchers have conducted a multitude of calculations using hybrid models [70][71][72][73][74][75][76]. These studies have obtained shocktype solutions both with and without a wave chain.…”

Section: Slow Shocksmentioning

confidence: 97%

“…These studies have obtained shocktype solutions both with and without a wave chain. According to [70,73], there is a critical Mach number Me = 0.98 such that for SS with 1 > M~ > Mc the downstream region contains a coherent wave chain, while for SS with MI < Me the rotational wave in the downstream region decays over a distance shorter than the wavelength. (For the magnetic tail SS with 0Bn= 75 ~ [~ 1 = 0.1, and Tel / Til = 0, the critical value is Me = 0.975 [73].)…”

Section: Slow Shocksmentioning

confidence: 99%

Hybrid simulation of space plasmas: Models with massless fluid representation of electrons. II. Slow and intermediate shocks

Filippychev¹

2000

Comput Math Model

View full text Add to dashboard Cite

This is a second article in a series of reviews on hybrid simulation of low-frequency processes in space plasmas. A hybrid model is described with ions represented by particles and electrons by a massless fluid. The main numerical schemes for the implementation of this model are described: the generalized Ohm law scheme and the predictor-corrector scheme. The first part of the article provides basic background information: MHD models (ideal, resistive, and Hall model); the Rankine-Hugoniot relationship for MHD discontinuities; the Hoffman-Teller coordinate system; and a classification of discontinuities. The review part of the article surveys the literature on simulation of slow shocks (including switch-off shocks) and intermediate shocks. The survey of literature on hybrid simulation of intermediate shocks is concluded with a review of studies that use two different numerical codes (the hybrid model and the resistive Hall MHD model). The computation results produced by the two codes are compared. The concluding part presents some remarks concerning the existence of intermediate shocks and their relationship with rotational discontinuities in various numerical models (ideal MHD, resistive MHD, the hybrid model).

show abstract

“…The two distances for the first plasmoid are consistent with the mid-tail and distant X-lines, and for the second plasmoid with the near-Earth and distant X-lines. However the size of the plasmoid in X may be less than the distance between the two X-lines, because a plasmoid is a plasma bulge and the bulge does not necessarily start from the position of the X-line: there can be a thin plasma sheet region between the X-line and the bulge (e.g., Lee et al, 1989). Also, the spacecraft may not encounter the full length of the plasmoid, leading to an underestimation of the plasmoid length.…”

Section: Discussionmentioning

confidence: 99%

A Quasi-stagnant Plasmoid Observed With Geotail on October 15, 1993

Kawano

Nishida

Fujimoto

et al. 1996

J. geomagn. geoelec

View full text Add to dashboard Cite

Slow shock characteristics as a function of distance from the X‐line in the magnetotail

Cited by 33 publications

References 23 publications

Generation of shock/discontinuity compound structures through magnetic reconnection in the geomagnetic tail

Generation of shock/discontinuity compound structures through magnetic reconnection in the geomagnetic tail

Hybrid simulation of space plasmas: Models with massless fluid representation of electrons. II. Slow and intermediate shocks

A Quasi-stagnant Plasmoid Observed With Geotail on October 15, 1993

Contact Info

Product

Resources

About