An ISEE 3 study of average and substorm conditions in the distant magnetotail

Slavin, J. A.; Smith, E. J.; Sibeck, D. G.; Baker, D. N.; Zwickl, R. D.; Akasofu, S.‐I.

doi:10.1029/ja090ia11p10875

Cited by 325 publications

(275 citation statements)

References 93 publications

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“…In reality, the region of acceleration may be some distance from the observation site. Slavin et al [1985] have described the change in lobe density and magnetic field with respect to downtail distance. They find that in the region X > -100 RE, the lobe density increases with downtail distance, as the plasma mantle fills in the lobes, while the magnetic field strength decreases.…”

Section: Resultsmentioning

confidence: 99%

Observations of slow flows in the distant plasma sheet

Mist¹,

Owen²

1999

J. Geophys. Res.

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Abstract.A statistical analysis of the properties of the plasma sheet in the geomagnetic tail using the ISEE 3 deep-tail data set is undertaken. The observed plasma sheet properties are compared to predictions of two models of reconnection.The first model [Cowley, 1980;Cowley and Southwood, 1980] is based on the balance of stress between a cold plasma inflow and the magnetic tension of reconnected field lines at the current sheet. The second [Owen et al., 1991] makes an attempt to incorporate heating of the plasma sheet population into this class of model. We find that only 60% of all plasma sheet events show densities greater than that in the adjacent lobe, as would be expected on the basis of mass conservation in the reconnection models. In addition, comparison of the distribution of the predicted velocities with the observed velocities shows that for a significant proportion of events, neither reconnection model accurately predicts the observed flows. In fact, the plasma sheet is most often seen to be in a quasi-stagnant state. During periods of tailward convection, the heated model appears the more appropriate for describing plasma sheet flow due to reconnection. However, in the case of the heated (simple) model, at least 50% (60%) of tailward flows are observed at velocities well below the predictions. These events also have positive B z on average and may therefore be associated with the tailward transport of closed flux tubes. They are also associated with geomagnetically quiet times. Such events are seen at all distance between-60 and-240 R• in the plasma sheet. These results strongly support previous suggestions that even at large downtail distances, the observed plasma sheet flows are often driven by processes other than reconnection. While the models correctly predict a significant proportion of the flow speeds for tailward flows, the earthward flow events are not well described by either model. In summary, 40% of the data set cannot be described by the reconnection models due to mass conservation requirements, and at most only 50% of the tailward flow speeds are in agreement with the predictions of these models. As such, only 30% of tailward flow events are well described by the models presented here.

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Section: Resultsmentioning

confidence: 99%

Observations of slow flows in the distant plasma sheet

Mist¹,

Owen²

1999

J. Geophys. Res.

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“…[33] The model has not explicitly addressed the issue of closed field line regions sometimes observed in the flanks of the magnetotail at distances of a few hundred R E [e.g., Slavin et al, 1985]; it has been suggested that these are associated with a curved distant X-line [Slavin et al, 1985] or are nearEarth flank field lines which have been carried downtail by diffusive momentum transfer from the magnetosheath [e.g., Mist and Owen, 2002]. We offer an alternative interpretation, noting that draped c+ open field lines produced by lobe reconnection will coat the flanks of the tail with regions of B z -positive magnetic field, which could be misinterpreted as closed field lines if viewed in the equatorial plane.…”

Section: Discussionmentioning

confidence: 99%

“…The transport of open flux from the dayside to the nightside owing to the antisunward flow of the solar wind is now known as the Dungey convection cycle [Dungey, 1961[Dungey, , 1963 and results in the formation of a magnetotail of length $1000 R E [Dungey, 1965]. There is also a ''disconnected'' tail, which comprises the highly kinked solar wind field lines newly reconnected at C. It is now thought that reconnection can take place at two locations in the magnetotail: at a ''distant'' X-line $150 R E downtail during quiet times [e.g., Slavin et al, 1985], and a ''near-Earth'' X-line during substorms near 20-30 R E [e.g., Siscoe and Cummings, 1969;McPherron et al, 1973;Russell and McPherron, 1973]. The only tail X-line that is of importance to this study is the one that is actively reconnecting open lobe field lines, and in the rest of this paper tail reconnection is considered as a single process.…”

Section: Magnetotail Modelmentioning

confidence: 99%

A simple model of the flux content of the distant magnetotail

Milan

2004

J. Geophys. Res.

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A simple model is presented which allows the profile of open flux within the magnetotail lobes to be determined from a knowledge of the present size of the polar cap and the past history of low‐latitude and high‐latitude dayside reconnection. The model shows that the nominal length of the tail is dependent on the elapsed time since reconnection of the oldest open field lines and that a much longer disconnected tail and wake can exist beyond this. The model is applied to two 8‐hour intervals of observations, which indicate that the length of the tail can vary by almost a factor of 10, between ∼400 and 4000 RE, in just a few hours. In addition, differing rates of lobe reconnection in the Northern and Southern Hemispheres are shown to lead to considerable differences in the lengths of the two magnetotail lobes.

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“…It is also generally assumed, that reconnection of lobe field lines occurs at almost any time. During geomagnetically quiet times, reconnection is believed to occur in the distant tail at an X-line that is located around 100 RE from earth [Slavin et al, 1985], while during geomagnetically active times, one or more X-lines develop closer to earth, leading to the formation of plasmoids or flux ropes that are ejected through the distant tail [Hones, 1979]. The models predict that convection associated with the reconnection sites is generally earthward on the earthward side of an X-line and tailward on the tailward side [Dungey, 1961;Cowley, 1980].…”

Section: Introductionmentioning

confidence: 99%