Current structures associated with dipolarization fronts

Yao, Zhonghua; Sun, W.; Fu, S. Y.; Pu, Z. Y.; Liu, Jiang; Angelopoulos, V.; Zhang, X.-J.; Chu, Xiangning; Shi, Quanqi; Guo, Ruilong; Zong, Qiugang

doi:10.1002/2013ja019290

Cited by 64 publications

(110 citation statements)

References 26 publications

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“…4 that was not shown in the current system described in Fig. 4b by Yao et al (2013), we suggest this pressure increase may be caused by the compression of the plasma flow behind the DF. This dawnward current is naturally expected from Fig.…”

Section: The Re-distribution Of Cross-tail Current Densitymentioning

confidence: 50%

“…This B z signature is seen for all distance ranges shown in the figure. Yao et al (2013) showed that such a dip in the magnetic field ahead of DFs is a common, and found that field-aligned currents usually exist in this region. We now compare DFs based on the magnitude of the change in B z prior to the DF arrival.…”

Section: Data Setmentioning

confidence: 99%

“…Figure 4b is a cartoon illustrating the banana current loop between the magnetic dip region and the dipolarization front layer. This cartoon presents similar current system as the current system associated with DF in Yao et al (2013), however, they represent a very different physical process. In Yao et al (2013), the dawnward and duskward currents are the current system of DF, while here the dawnward and duskward currents are additional structures asso- ciated with the magnetic dip.…”

Section: The Re-distribution Of Cross-tail Current Densitymentioning

confidence: 99%

“…This cartoon presents similar current system as the current system associated with DF in Yao et al (2013), however, they represent a very different physical process. In Yao et al (2013), the dawnward and duskward currents are the current system of DF, while here the dawnward and duskward currents are additional structures asso- ciated with the magnetic dip. In addition, the difference of magnetic field B z is almost the same at t 0 -10 s and t 0 + 10 s, which strongly suggests that these three current form circuits, which are independent from the background magnetotail current.…”

Section: The Re-distribution Of Cross-tail Current Densitymentioning

confidence: 99%

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A physical explanation for the magnetic decrease ahead of dipolarization fronts

Yao¹,

Liu

Owen³

et al. 2015

Ann. Geophys.

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Abstract.Recent studies have shown that the ambient plasma in the near-Earth magnetotail can be compressed by the arrival of a dipolarization front (DF). In this paper we study the variations in the characteristics of currents flowing in this compressed region ahead of the DF, particularly the changes in the cross-tail current, using observations from the THEMIS satellites. Since we do not know whether the changes in the cross-tail current lead to a field-aligned current formation or just form a current loop in the magnetosphere, we thus use redistribution to represent these changes of local current density. We found that (1) the redistribution of the cross-tail current is a common feature preceding DFs; (2) the redistribution of cross-tail current is caused by plasma pressure gradient ahead of the DF and (3) the resultant net current redistributed by a DF is an order of magnitude smaller than the typical total current associated with a moderate substorm current wedge (SCW). Moreover, our results also suggest that the redistributed current ahead of the DF is closed by currents on the DF itself, forming a closed current loop around peaks in plasma pressure, what is traditionally referred to as a banana current.

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Section: The Re-distribution Of Cross-tail Current Densitymentioning

confidence: 50%

Section: Data Setmentioning

confidence: 99%

Section: The Re-distribution Of Cross-tail Current Densitymentioning

confidence: 99%

Section: The Re-distribution Of Cross-tail Current Densitymentioning

confidence: 99%

See 2 more Smart Citations

A physical explanation for the magnetic decrease ahead of dipolarization fronts

Yao¹,

Liu

Owen³

et al. 2015

Ann. Geophys.

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“…The current disruption started at the leading edge of the flow, as a sharp dipolarization front (DF) with a magnetic dip ahead of the front layer. The magnetic dip current, which is of Region 2 sense, has been studied recently [Liu et al, 2013a[Liu et al, , 2013bYao et al, 2013b;Sun et al, 2013]. Those studies presented the FAC features ahead of the DF, while this paper has studied the cross-tail current density evolution ahead of earthward flow.…”

Section: Discussionmentioning

confidence: 99%

Current reduction in a pseudo‐breakup event: THEMIS observations

Yao

Owen³

et al. 2014

JGR Space Physics

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Pseudo-breakup events are thought to be generated by the same physical processes as substorms. This paper reports on the cross-tail current reduction in an isolated pseudo-breakup observed by three of the THEMIS probes (THEMIS A (THA), THEMIS D (THD), and THEMIS E (THE)) on 22 March 2010. During this pseudo-breakup, several localized auroral intensifications were seen by ground-based observatories. Using the unique spatial configuration of the three THEMIS probes, we have estimated the inertial and diamagnetic currents in the near-Earth plasma sheet associated with flow braking and diversion. We found the diamagnetic current to be the major contributor to the current reduction in this pseudo-breakup event. During flow braking, the plasma pressure was reinforced, and a weak electrojet and an auroral intensification appeared. After flow braking/diversion, the electrojet was enhanced, and a new auroral intensification was seen. The peak current intensity of the electrojet estimated from ground-based magnetometers,~0.7 × 10 5 A, was about 1 order of magnitude lower than that in a typical substorm. We suggest that this pseudo-breakup event involved two dynamical processes: a current-reduction associated with plasma compression ahead of the earthward flow and a current-disruption related to the flow braking/diversion. Both processes are closely connected to the fundamental interaction between fast flows, the near-Earth ambient plasma, and the magnetic field.

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On the role of pressure and flow perturbations around dipolarizing flux bundles

et al. 2013

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[1] As a dipolarizing flux bundle (DFB) moves earthward, it creates pressure and flow perturbations. These perturbations may play a significant role in controlling DFB motion and generating field-aligned currents (FACs) which render the DFB a "wedgelet", a traveling building block of the substorm current wedge. To investigate this hypothesis, we use DFB observations from the Time History of Events and Macroscale Interactions during Substorms mission to reconstruct the spatial profiles of the thermal and total (thermal plus magnetic) pressures and of the plasma flow near the DFB. The total pressure reaches maximum inside the dipolarization front (DF, the leading edge of the DFB). The resultant pressure gradient force pushes ambient plasma in the direction normal to the front and exerts a gradient force density of~0.15 nPa/R E against the DFB motion. The thermal pressure in the equatorial plane is strongest immediately ahead of the DFB's leading point; it decreases with distance from that peak: toward the ambient plasma, toward the DFB interior, and toward the DFB flanks. Combining our estimate of the flux tube volume distortion with the measured equatorial thermal pressure distribution, we obtain a region-1-sense FAC inside the DF layer and region-2-sense FAC in the~1 R E thick region immediately ahead of it. This system of FACs is indeed consistent with a wedgelet.

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Current structures associated with dipolarization fronts

Cited by 64 publications

References 26 publications

A physical explanation for the magnetic decrease ahead of dipolarization fronts

A physical explanation for the magnetic decrease ahead of dipolarization fronts

Current reduction in a pseudo‐breakup event: THEMIS observations

On the role of pressure and flow perturbations around dipolarizing flux bundles

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