Scale sizes of intense auroral electric fields observed by Cluster

Johansson, Tommy; Marklund, Göran; Karlsson, Tomas; Liléo, S.; Lindqvist, Per‐Arne; Nilsson, Hans; Buchert, Stephan

doi:10.5194/angeo-25-2413-2007

Cited by 19 publications

(16 citation statements)

References 47 publications

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“…Karlsson and Marklund (1996) found that the potential variation across the E-field structure has the same order of magnitude for all events and is independent on the E-field peak scale-size. Johansson et al (2007) get similar results for monopolar events when disregarding those scale-size ranges with very large error bars (not shown in their paper is that the same relation appears when all bipolar and monopolar events are merged into one group). Even for thin field-aligned current sheets connected to discrete arcs an inverse relationship between FAC width and FAC intensity has been found Stasiewicz and Potemra, 1998).…”

Section: Connection To Different Substorm Phasessupporting

confidence: 62%

“…Thus, Haerendel (2000) concluded that the overall plasma convection will not be enhanced by discrete arcs, only the energy conversion rate. However, observations by Johansson et al (2007) of a preferred occurrence of intense E-field events at density boundaries and their often non-bipolar shape indicate that rapid flows along discrete arcs (and their return currents) lead to a net plasma flux. Due to the high velocities of these flows, the net flux above arcs could play an important role for the total plasma transport from the nightside to the dayside.…”

Section: Possible Connection Between Discrete Arcs and Plasma Convectionmentioning

confidence: 99%

“…Even more important for the unequal amount of plasma flux on the different sides of discrete arcs is the non-bipolar shape of the intense E-field structure. Johansson et al (2007) showed that 75% of the intense E-field peaks have a monopolar shape. A case by case inspection of our dataset reveals that, in contrast to the example shown in Fig.…”

Section: Connection To Different Substorm Phasesmentioning

confidence: 99%

“…In the large statistical study by Johansson et al (2007), covering all intense E-field events above 150 mV/m between 2001 and 2003, only 13% of all detected E-field peaks have magnitudes above 500 mV/m. The low number of strong E-field peaks has its reason in the high-latitude orbit of the Cluster satellites.…”

Section: The Spatial Distribution Of Intense E-field Eventsmentioning

confidence: 99%

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Plasma transport along discrete auroral arcs and its contribution to the ionospheric plasma convection

et al. 2008

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Abstract. The role of intense high-altitude electric field (Efield) peaks for large-scale plasma convection is investigated with the help of Cluster E-field, B-field and density data. The study covers 32 E-field events between 4 and 7 R E geocentric distance, with E-field magnitudes in the range 500-1000 mV/m when mapped to ionospheric altitude. We focus on E-field structures above the ionosphere that are typically coupled to discrete auroral arcs and their return current region. Connected to such E-field peaks are rapid plasma flows directed along the discrete arcs in opposite directions on each side of the arc.Nearly all the E-field events occur during active times. A strong dependence on different substorm phases is found: a majority of intense E-field events appearing during substorm expansion or maximum phase are located on the nightside oval, while most recovery events occur on the dusk-todayside part of the oval. For most expansion and maximum phase cases, the average background plasma flow is in the sunward direction. For a majority of recovery events, the flow is in the anti-sunward direction.The net plasma flux connected to a strong E-field peak is in two thirds of the cases in the same direction as the background plasma flow. However, in only one third of the cases the strong flux caused by an E-field peak makes an important contribution to the plasma transport within the boundary plasma sheet. For a majority of events, the area covered by rapid plasma flows above discrete arcs is too small to have Correspondence to: A. Kullen (kullen@irfu.se) an effect on the global convection. This questions the role of discrete auroral arcs as major driver of plasma convection.

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Section: Connection To Different Substorm Phasessupporting

confidence: 62%

Section: Possible Connection Between Discrete Arcs and Plasma Convectionmentioning

confidence: 99%

Section: Connection To Different Substorm Phasesmentioning

confidence: 99%

Section: The Spatial Distribution Of Intense E-field Eventsmentioning

confidence: 99%

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Plasma transport along discrete auroral arcs and its contribution to the ionospheric plasma convection

et al. 2008

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“…Recently, 5 years of the Fast Auroral SnapshoT Explorer (FAST) data have shown that the usual width of an inverted-V varies from 20 to 40 km, which is comparable to the peak value of the typical mesoscale auroral arc width of 10-20 km (Partamies et al, 2008). From Freja and Cluster observations, the scale sizes of auroral electric field structures were reported to be ∼ 1-5 km (Karlsson and Marklund, 1996;Johansson et al, 2007). However, these dimensions are much larger than the dimensions of a typical aurora.…”

Section: Introductionmentioning

confidence: 91%

Relating field-aligned beams to inverted-V structures and visible auroras

Lee

Parks

et al. 2015

Ann. Geophys.

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Abstract. The ion composition experiment on Cluster measures 3-D distributions in one spin of the spacecraft (4 s).These distributions often measure field-aligned ion beams (H + , He + and O + ) accelerated out of the ionosphere. The standard model of these beams relies on a quasi-static Ushaped potential model. The beams contain important information about the structure and distribution of the U-shaped potential structures. For example, a simple beam with a narrow velocity range tells us that the particles are accelerated going through a quasi-static U-shaped potential structure localized in space. A more complex beam with a large range of velocities varying smoothly (a few tens of kilometers per second to > 100 km s −1 ) tells us that the potential structure is extended and distributed along the magnetic field. The Cluster experiment has now revealed new features about the beams. Some beams are broken into many individual structures each with their own velocity. The U-shaped potential model would interpret the new features in terms of particles accelerated by narrow isolated potential structures maintained over an extended region of the magnetic field. Another interpretation is that these features arise as Cluster traverses toward the center of a small-scale U-shaped potential region detecting particles accelerated on different equipotential contours. The estimate of the distance of the adjacent contours is ∼ 590-610 m at a Cluster height of ∼ 3.5 R E . The observed dimensions map to ∼ 295-305 m in the ionosphere, suggesting Cluster has measured the potential structure of an auroral arc.

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