Statistical study of high-latitude plasma flow during magnetospheric substorms

Provan, G.; Lester, M.; Mende, S. B.; Milan, S. E.

doi:10.5194/angeo-22-3607-2004

Cited by 57 publications

(82 citation statements)

References 38 publications

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“…Indeed, the fact that these flows clearly cross the open-closed field line boundary implies reconnection driven flow. The development of these flows over the course of the expansion phase, rather than an instantaneous appearance at the time of substorm onset, is corroborated by other recent studies such as those of Jayachandran et al (2003) and Provan et al (2004) which also show a large-scale reaction in the flows over the ∼10-20 mins following substorm onset. What is clear from this study, however, is the addition to these flows of other large-scale flow features, which have previously only been discussed individually.…”

Section: The Large-scale Picturesupporting

confidence: 71%

“…Grocott et al (2000Grocott et al ( , 2002 presented analyses of Super Dual Auroral Radar Network (SuperDARN) flow data obtained during isolated substorms, and have found evidence for the excitation of twin-vortex flow cells centred in the nightside ionosphere, which enhance the transpolar voltage by ∼40 kV compared with pre-onset values. Following this work, Provan et al (2004) conducted a statistical study of substorm flows and found them to become enhanced across the polar cap and in the low-latitude return flow region. They also found a systematic increase in the transpolar voltage from ∼40 kV 2 min before onset to ∼75 kV 12 min after, and attributed this to the removal of open flux from the polar cap by nightside reconnection.…”

Section: Introductionmentioning

confidence: 99%

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Towards a synthesis of substorm electrodynamics: HF radar and auroral observations

et al. 2006

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Abstract. At 08:35 UT on 21 November 2004, the onset of an interval of substorm activity was captured in the southern hemisphere by the Far UltraViolet (FUV) instrument on board the IMAGE spacecraft. This was accompanied by the onset of Pi2 activity and subsequent magnetic bays, evident in ground magnetic data from both hemispheres. Further intensifications were then observed in both the auroral and ground magnetic data over the following ∼3 h. During this interval the fields-of-view of the two southern hemisphere Tasman International Geospace Enviroment Radars (TIGER) moved through the evening sector towards midnight. Whilst initially low, the amount of backscatter from TIGER increased considerably during the early stages of the expansion phase such that by ∼09:20 UT an enhanced dusk flow cell was clearly evident. During the expansion phase the equatorward portion of this flow cell developed into a narrow high-speed flow channel, indicative of the auroral and subauroral flows identified in previous studies (e.g. Freeman et al., 1992;Parkinson et al., 2003). At the same time, higher latitude transient flow features were observed and as the interval progressed the flow reversal region and Harang discontinuity became very well defined. Overall, this study has enabled the spatial and temporal development of many different elements of the substorm process to be resolved and placed within a simple conceptual framework of magnetospheric convection. Specifically, the detailed observations of ionospheric flows have illustrated the complex interplay between substorm electric fields and associated auroral dynamics. They have helped define the distinct nature of different substorm current systems such as the traditional substorm current wedge and the more equatorward currents associated with polarisation electric fields. Additionally, they have Correspondence to: A. Grocott (a.grocott@ion.le.ac.uk) revealed a radar signature of nightside reconnection which provides the promise of quantifying nightside reconnection in a way which has already proved extremely successful in studies of the dayside magnetosphere.

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Section: The Large-scale Picturesupporting

confidence: 71%

Section: Introductionmentioning

confidence: 99%

Towards a synthesis of substorm electrodynamics: HF radar and auroral observations

et al. 2006

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“…Further studies using SuperDARN have produced mixed results, however, by providing evidence for both the excitation (e.g. Grocott et al, 2006;Provan et al, 2004) and reduction (e.g. Lyons et al, 2001;Bristow and Jensen, 2007) of the flows following substorm onset.…”

Section: Introductionmentioning

confidence: 99%

Superposed epoch analysis of the ionospheric convection evolution during substorms: onset latitude dependence

et al. 2009

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Abstract. Using data from the Super Dual Auroral Radar Network (SuperDARN) we investigate the ionospheric convection response to magnetospheric substorms. Substorms were identified using the Far Ultraviolet (FUV) instrument on board the Imager for Magnetopause-to-Aurora Global Exploration (IMAGE) spacecraft, and were then binned according to the magnetic latitude of their onset. A superposed epoch analysis of the ionospheric convection patterns for each onset-latitude bin was then performed using radar data for the interval 60 min before onset to 90 min after. It is found that lower onset-latitude substorms are associated with generally more enhanced convection than the higher latitude substorms, although they suffer from a significant localised reduction of the flow in the midnight sector during the expansion phase. Higher-latitude substorms are associated with a significant and rapid increase in the nightside convection following substorm onset, with all onset-latitude bins showing an enhancement over onset values by ∼60 min into the expansion phase. A rudimentary inspection of the concurrent auroral evolution suggests that the duration of the flow reduction following substorm onset is dependent on the strength and duration of the expansion phase aurora and its associated conductivity enhancement.

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“…The two currently available techniques of direct CPCP measurements, i.e., via satellite ion drift data (Hairston et al, 1998) and ground-based radars Grocott et al, 2002;Provan et al, 2004), are both incomplete. This is due to the limited temporal resolution of the satellite measurements, on one hand, and the missing spatial coverage at high latitudes of the present radars, on the other.…”

Section: Introductionmentioning

confidence: 99%

“…The relative contributions to the cross-polar cap potential (CPCP) from the dayside (CPCP/day) and nightside (CPCP/night) sources during intervals of substorm activity have been studied in recent years, applying different observational techniques (Bristow et al, 2004;Lockwood et al, 2009;Kullen et al, 2010;Gordeev et al, 2011;Andalsvik et al, 2011Andalsvik et al, , 2012. Fox et al (1999), Grocott et al (2002) and Provan et al (2004) estimated the convection response to isolated substorms by continuous observations, applying a ground-based radar technique. Grocott et al (2010) studied the convection responses in the dayside and nightside sectors of the polar cap to substorms occurring during intervals of positive and negative interplanetary magnetic field (IMF) B y polarity, applying a superposed epoch analysis.…”

Section: Introductionmentioning

confidence: 99%

The pulsed nature of the nightside contribution to polar cap convection: repetitive substorm activity under steady interplanetary driving

2012

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Abstract. The aim of this study is to investigate the relative contributions of dayside and nightside processes to the spatial and temporal structure of polar cap plasma convection. The central parameter is the cross-polar cap potential (CPCP). Selecting a 10-h-long interval of stable interplanetary driving by an interplanetary CME (ICME), we are able to distinguish between the dayside and nightside sources of the convection. The event was initiated by an abrupt enhancement of the magnetopause (MP) reconnection rate triggered by a southward turning of the ICME magnetic field. This was followed by a long interval (10 h) of steady and strong driving. Under the latter condition a long series of electrojet intensifications was observed which recurred at 50 min intervals. The detailed temporal structure of polar cap convection in relation to polar cap contraction events is obtained by combining continuous ground observations of convection-related magnetic deflections (including polar cap magnetic indices in the Northern and Southern Hemispheres, PCN and PCS) and the more direct, but lower-resolution ion drift data obtained from a satellite (DMSP F13) in polar orbit. The observed PCN enhancements combined with DMSP satellite observations (F13 and F15 data) of polar cap contractions during the evolution of selected substorm expansions allowed us to estimate the CPCP enhancements (25 %) associated with individual events in the series. Ground-satellite conjunctions are further used to investigate the spatial structure of polar cap convection, i.e., the homogeneous plasma flow in the centre (V i ≤ 1 km s −1 ) versus channels of enhanced antisunward flows (V i ≥ 1 km s −1 ) along the periphery of the polar cap. We emphasise the temporal structure of these polar cap flow phenomena in relation to the prevailing solar wind forcing and the repetitive substorm activity.

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Statistical study of high-latitude plasma flow during magnetospheric substorms

Cited by 57 publications

References 38 publications

Towards a synthesis of substorm electrodynamics: HF radar and auroral observations

Towards a synthesis of substorm electrodynamics: HF radar and auroral observations

Superposed epoch analysis of the ionospheric convection evolution during substorms: onset latitude dependence

The pulsed nature of the nightside contribution to polar cap convection: repetitive substorm activity under steady interplanetary driving

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