Storm time current distribution in the inner equatorial magnetosphere: THEMIS observations

Yang, Yanchu; Shen, C.; Dunlop, Malcolm; Rong, Zhaojin; Li, X.; Angelopoulos, V.; Chen, Z. Q.; Yan, Guoguo; Ji, Yong

doi:10.1002/2015ja022145

Cited by 24 publications

(35 citation statements)

References 44 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The curlometer can be applied to residual measured fields which result after first subtracting a zero-current model field from the measured magnetic field, however, and this minimises such effects. Indeed it is necessary in the high field regions of the magnetosphere and ionosphere (Yang et al 2016;Dunlop et al 2015). The use of a defined model field containing no current density is usually sufficient and of course it is usually desirable that any de-trending of the data in this way should not remove any real currents which may be present.…”

Section: Cluster Lessons: Implementation Scale Size and Stationaritymentioning

confidence: 99%

Multi-spacecraft Current Estimates at Swarm

Dunlop

Yang

Yang³

et al. 2019

Ionospheric Multi-Spacecraft Analysis Tools

View full text Add to dashboard Cite

In this chapter the application of the curlometer technique to various regions of the inner magnetosphere and upper ionosphere and for special circumstances of sampling is described. The basic technique is first outlined, together with the caveats of use, covering: the four-spacecraft technique, its quality factor and limitations; the lessons learnt from Cluster data, together with issues of implementation, scale size and stationarity, and description of the key regions covered by related methodology. Secondly, the application to the Earth's ring current region is outlined, covering: the application of Cluster crossings to survey the ring current; the use of the MRA (magnetic rotation analysis) method for field curvature analysis; the use of THEMIS (Time History of Events and Macroscale Interactions during Sub-storms mission) three-spacecraft configurations to sample the ring current, and future use of MMS (Magnetospheric MultiScale mission) and Swarm data, i.e. the case of small separations. Thirdly, the application of the technique to the low altitude regions covered by Swarm is outlined, covering: the extension of the method to stationary signals; the use of special configurations and adjacent times to achieve 2, 3, 4, 5 point analysis; the use of the extended 'curlometer' with Swarm close configurations to compute 3-D current density, and a brief indication of the computation of current sheet orientation implied by 2-spacecraft correlations. Fourthly, the direct coordination of Cluster and Swarm to check the scaling and coherence of field-aligned currents (FACs) is outlined.

show abstract

Section: Cluster Lessons: Implementation Scale Size and Stationaritymentioning

confidence: 99%

Multi-spacecraft Current Estimates at Swarm

Dunlop

Yang

Yang³

et al. 2019

Ionospheric Multi-Spacecraft Analysis Tools

View full text Add to dashboard Cite

show abstract

“…The huge progress in satellite deployments makes it possible for direct observation of the inner-magnetosphere current system. It is believed that the magnetosphere and ionosphere are linked through a ring current (RC) and FACs (e.g., Le et al, 2004;Zhang et al, 2011). Therefore, many investigations are mainly focused on these two current systems, from high (e.g., Potemra, 1976, 1978;Wang et al, 2006;Dunlop et al, 2015a) to low latitudes (e.g., Vallat et al, 2005;Shen et al, 2014;Yang et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Strong southward and northward currents observed in the inner plasma sheet

Yang¹,

Shen²,

Ji³

2019

Ann. Geophys.

View full text Add to dashboard Cite

It is generally believed that field-aligned currents (FACs) and the ring current (RC) are two dominant parts of the inner magnetosphere. However, using the Cluster spacecraft crossing the pre-midnight inner plasma sheet in the latitudinal region between 10 and 30 • N, it is found that, during intense geomagnetic storms, in addition to FACs and the RC, strong southward and northward currents also exist which should not be FACs because the magnetic field in these regions is mainly along the x-y plane. Detailed investigation shows that both magnetic-field lines (MFLs) and currents in these regions are highly dynamic. When the curvature of MFLs changes direction in the x-y plane, the current also alternatively switches between being southward and northward. To investigate the generation mechanism of the southward and northward current, we employed the analysis of energetic particle flux up to 1 MeV. For energetic particles below 40 keV, observations from Cluster CIS/CODIF (Cluster Ion Spectrometry COmposition and DIstribution Function analyzer) are used. However, for higher-energy particles, the flux is obtained by extrapolations of low-energy particle data through Kappa distribution. The result indicates that the most reasonable cause of these southward and northward currents is the curvature drift of energetic particles.Published by Copernicus Publications on behalf of the European Geosciences Union.

show abstract

“…It is believed that the magnetosphere and ionosphere are linked through a ring current (RC) and field-aligned currents (FACs) (e.g., Le et al 2004;Zhang et al 2011). Therefore, many investigations are mainly focused on these two 25 current systems, respectively, from high latitude (e.g., Iijima and Potemra 1976;1978;Wang et al, 2006;Dunlop et al, 2015b) and low latitude (e.g., Vallat et al 2005;Shen et al 2014;Yang et al 2016). The region from low to middle latitude, which is the key area for the inner magnetosphere current link, however, has received less attention.…”

Section: Introductionmentioning

confidence: 99%

Strong Southward and Northward Currents Observed in the Inner Plasma Sheet

Yue¹,

Shen²,

Ji³

2019

Preprint

View full text Add to dashboard Cite

Abstract. It is generally believed that field aligned currents (FACs) and the ring current (RC) are two dominant parts of the inner magnetosphere. However, using the Cluster spacecraft crossing of the pre-midnight inner plasma sheet in the latitude region between 10° N and 30° N, it is found that, during large storm events, in addition to FACs and the RC, there also exist strong southward and northward currents, which cannot be FACs, because the magnetic field in these regions is mainly along the XY plane. Detailed investigation shows that both magnetic field lines (MFLs) and currents in these regions highly fluctuate. When the curvature of MFLs changes direction in the XY plane, the current also alternatively switches between southward and northward. Further analysis of the current generation mechanism indicates that the most reasonable candidate for the origin of these southward and northward currents is the curvature drift of energetic particles.

show abstract

Storm time current distribution in the inner equatorial magnetosphere: THEMIS observations

Cited by 24 publications

References 44 publications

Multi-spacecraft Current Estimates at Swarm

Multi-spacecraft Current Estimates at Swarm

Strong southward and northward currents observed in the inner plasma sheet

Strong Southward and Northward Currents Observed in the Inner Plasma Sheet

Contact Info

Product

Resources

About