Polar patches observed by ESR and their possible origin in the cusp region

Smith, A. M.; Pryse, S. E.; Kersley, L.

doi:10.1007/s00585-000-1043-5

Cited by 17 publications

(15 citation statements)

References 19 publications

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“…This time history also shows that electron density features that are closer to the region of particle impact ionization are more structured than those farther along track, which are evolving into the classic asymmetric and flat‐topped shape of a polar cap patch. The time history of patch morphology created by this technique provides more context and can resolve shorter timescale changes than previous in situ observations [e.g., Smith et al , ].…”

Section: Analysis and Discussioncontrasting

confidence: 91%

“…These are the first in situ observations of a series of patches, entrained in the polar cap flow, traveling from their source in the cusp to the nightside auroral oval. The observations contrast the classical view of polar cap patch formation that solar EUV‐ionized patches are chopped off from the tongue of ionization and structure is added by the GDI acting on the trailing edge [ Gondarenko and Guzdar , ]. Instead, we observe cusp precipitation that produces large plasma density structures [e.g., Kelley et al , ; Walker et al , ; Smith et al , ] near noon that convect across the polar cap and smooth into classical polar cap patches. We conclude that the resulting kilometer‐scale structures are the product of particle impact ionization in the cusp.…”

Section: Discussionmentioning

confidence: 99%

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Swarm in situ observations of F region polar cap patches created by cusp precipitation

Goodwin

Iserhienrhien

Miles

et al. 2015

Geophysical Research Letters

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High‐resolution in situ measurements from the three Swarm spacecraft, in a string‐of‐pearls configuration, provide new insights about the combined role of flow channel events and particle impact ionization in creating F region electron density structures in the northern Scandinavian dayside cusp. We present a case of polar cap patch formation where a reconnection‐driven low‐density relative westward flow channel is eroding the dayside solar‐ionized plasma but where particle impact ionization in the cusp dominates the initial plasma structuring. In the cusp, density features are observed which are twice as dense as the solar‐ionized background. These features then follow the polar cap convection and become less structured and lower in amplitude. These are the first in situ observations tracking polar cap patch evolution from creation by plasma transport and enhancement by cusp precipitation, through entrainment in the polar cap flow and relaxation into smooth patches as they approach the nightside auroral oval.

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Section: Analysis and Discussioncontrasting

confidence: 91%

Section: Discussionmentioning

confidence: 99%

Swarm in situ observations of F region polar cap patches created by cusp precipitation

Goodwin

Iserhienrhien

Miles

et al. 2015

Geophysical Research Letters

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“…There are several proposed methods on how the TOI is restructured into patches, such as the IMF controlled alterations in the cusp inflow region [c.f. Sojka et al , 1993; Smith et al , 2000], convection jets (also known as flow‐channel events) [ Rodger et al , 1994], convection vortices [ Schunk et al , 1994; Valladares et al , 1996; Decker et al , 1994], polar cap expansion and contraction [ Anderson et al , 1988], and linked to the latter, an expansion of the polar cap convection driven by pulsed reconnection [ Lockwood and Carlson , 1992].…”

Section: Introductionmentioning

confidence: 99%

Drifting airglow patches in relation to tail reconnection

Lorentzen¹,

Shumilov²,

Moen

2004

Geophysical Research Letters

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[1] In this study we present optical ground-based signatures of drifting airglow patches in the polar ionospheric F-layer, in the evening/nighttime MLT sector. The patches were observed under predominately IMF B Z < 0, IMF B Y > 0 conditions, which are favorable for highdensity sunlit plasma to be entrained into the polar cap with the large afternoon cell in the northern hemisphere. The patch morphology, such as altitude, meridional convection speed, and repetition rate was investigated using a meridian scanning photometer, and put into the context of activity changes in the auroral substorm. It was found that the meridional patch speed was modulated by the ongoing substorms, and that the patches crossed the open/closed field line boundary (OCB), even during late recovery, and subsequent growth phase. We take this as an indication of ongoing tail reconnection, and we therefore propose that the patches can be used as a tracer for tail reconnection when they cross the OCB and enter the nighttime auroral oval.

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“…VOACAP and ICEPAC modeled values do not reproduce the daytime variations observed in the CADI measurements. One of the most discussed features in the polar ionosphere are the polar patches: enhancements of electron density caused by different mechanisms [ Smith et al , ; Carlson et al , ; Lockwood et al , ; Oksavik et al , ]. MacDougall and Jayachandran [] not only observed a higher patch activity in winter than in summer but also noted that the seasonal variation depends on the patch definition used.…”

Section: Discussionmentioning

confidence: 99%

Comparison of observed and predicted MUF(3000)F2 in the polar cap region

et al. 2015

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The maximum usable frequency for a 3000 km range circuit (MUF(3000)F2), computed from ionosonde measurements at Resolute (74.75 Predictions and observations show diurnal and seasonal variations; however, the VOACAP and ICEPAC models fail to reproduce the diurnal variation trend observed in the measurements during the summer period. The performance of these models has been statistically analysed: REC533 gives a better performance in winter and equinox months, while VOACAP has a better performance for both equinox and summer months. ICEPAC shows poor performance during low solar activity.

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Polar patches observed by ESR and their possible origin in the cusp region

Cited by 17 publications

References 19 publications

Swarm in situ observations of F region polar cap patches created by cusp precipitation

Swarm in situ observations of F region polar cap patches created by cusp precipitation

Drifting airglow patches in relation to tail reconnection

Comparison of observed and predicted MUF(3000)F2 in the polar cap region

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