Structure and dynamics of the winter polar cap <i>F</i> region

Büchau, J.; Reinisch, B. W.; Weber, E. J.; Moore, J. G.

doi:10.1029/rs018i006p00995

Cited by 161 publications

(148 citation statements)

References 10 publications

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“…A comprehensive review of the current understanding of the patch phenomenon has been given by Crowley (1996). Patches occur predominantly under conditions of IMF Bz southward and drift across the polar cap at speeds of typically 300± 1000 ms )1 (Buchau et al, 1983). They have been observed in summer and winter (Buchau and Reinisch, 1991) and have been seen to form in geomagnetically conjugate regions (Rodger et al, 1994a).…”

Section: Introductionmentioning

confidence: 99%

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

2000

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Abstract. Observations by the EISCAT Svalbard radar in summer have revealed electron density enhancements in the magnetic noon sector under conditions of IMF Bz southward. The features were identi®ed as possible candidates for polar-cap patches drifting anti-Sunward with the plasma¯ow. Supporting measurements by the EISCAT mainland radar, the CUTLASS radar and DMSP satellites, in a multi-instrument study, suggested that the origin of the structures lay upstream at lower latitudes, with the modulation in density being attributed to variability in soft-particle precipitation in the cusp region. It is proposed that the variations in precipitation may be linked to changes in the location of the reconnection site at the magnetopause, which in turn results in changes in the energy distribution of the precipitating particles.

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Section: Introductionmentioning

confidence: 99%

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

2000

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“…On any particular occasion, the actual flow patterns may differ significantly from those in the illustration. When the IMF is directed northwards (Bz > 0), the principal large-scale electron density structures within the polar cap ionosphere are Sun-aligned arcs (plasma striations extending for thousands of kilometers in the transpolar noon-midnight direction, but much narrower with scales around 100 km in the dawn-dusk direction [Buchau et al, 1983]). A series of arcs drifting steadily across the polar cap from dawn to dusk would lead to the expectation that increasing bearing swings would be observed during the time sector 1800 to 0600 LT, with the largest swings expected in the midnight sector.…”

Section: Overview Of Experimental Measurementsmentioning

confidence: 99%

“…During periods of southward directed Interplanetary Magnetic Field (IMF) (Bz < 0) and the associated high levels of geomagnetic activity, patches of plasma 100-1000 km across with electron density enhancements of up to a factor of 10 above the background densities have been observed in the high-latitude F region ionosphere. These drift antisunwards across the central polar cap at velocities of a few kilometers per second in the high latitude convection current flows Buchau et al, 1983]. When geomagnetic activity is low and the IMF is directed northward (Bz > 0) (approximately 50% of the time), Sun-Earth aligned arcs of plasma with electron density enhancements of a factor of 2-3 above the background can occur which drift across the polar cap at velocities of a few hundred meters per second, generally in a dusk-ward direction [Buchau et al, 1983].…”

Section: Introductionmentioning

confidence: 99%

“…These drift antisunwards across the central polar cap at velocities of a few kilometers per second in the high latitude convection current flows Buchau et al, 1983]. When geomagnetic activity is low and the IMF is directed northward (Bz > 0) (approximately 50% of the time), Sun-Earth aligned arcs of plasma with electron density enhancements of a factor of 2-3 above the background can occur which drift across the polar cap at velocities of a few hundred meters per second, generally in a dusk-ward direction [Buchau et al, 1983]. The plasma striations are elongated for thousands of kilometers in the transpolar noon-midnight direction but are much narrower (around 100 km) in the dawndusk direction.…”

Section: Introductionmentioning

confidence: 99%

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Simulation of off‐great circle HF propagation effects due to the presence of patches and arcs of enhanced electron density within the polar cap ionosphere

2003

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Observations over recent years have established that large‐scale electron density structures are a common feature of the polar cap F region ionosphere. These structures take the form of convecting patches and arcs of enhanced electron density which form tilted reflection surfaces for HF radiowaves, allowing off‐great circle propagation paths to be established. Numerical ray tracing has been employed to simulate the effects of these structures on the ray paths of the radiowaves. The simulations have reproduced the precise character of experimental observations of the direction of arrival over a propagation path within the polar cap and of oblique ionograms obtained over the same path.

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“…Of relevance to the current study are density enhancements on horizontal scales of ∼100 s to 1000 s km in the F-region, known as polar patches. These patches were studied first using ionospheric sounders and airglow emissions (Buchau et al, 1983;Weber et al, 1984), but they have since been investigated by a variety of experimental techniques, including radio scintillation (Buchau et al, 1985), incoherent scatter radar (Pedersen et al, 1998), HF radar (Ogawa et al, 1998) and radio tomography (Walker et al, 1999). However, comparisons of features observed by different techniques are not Correspondence to: S. E. Pryse (sep@aber.ac.uk) always straight-forward, with different techniques using different criteria to define a patch.…”

Section: Introductionmentioning

confidence: 99%

Reconfiguration of polar-cap plasma in the magnetic midnight sector

et al. 2006

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Abstract. Radio tomography and the EISCAT and Super-DARN radars have been used to identify long-lived, highaltitude, cold plasma in the antisunward convective flow across the polar cap. The projection of the feature to later times suggests that it was reconfigured in the Harang discontinuity to form an enhancement that was elongated in longitude in the sunward return flow of the high-latitude convection pattern. Comparison with a tomographic image at a later time supports the interpretation of a polar patch being reconfigured into a boundary blob. There is also evidence for a second plasma enhancement equatorward of the reconfigured blob, likely to have been produced by in situ precipitation. The observations indicate that the two mechanisms proposed in the literature for the production of boundary blobs are operating simultaneously to form two distinct density features separated slightly in latitude.

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Structure and dynamics of the winter polar cap F region

Cited by 161 publications

References 10 publications

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

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

Simulation of off‐great circle HF propagation effects due to the presence of patches and arcs of enhanced electron density within the polar cap ionosphere

Reconfiguration of polar-cap plasma in the magnetic midnight sector

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