On the possible role of cusp/cleft precipitation in the formation of polar-cap patches

Walker, I. K.; Moen, J.; Kersley, L.; Lorentzen, D. A.

doi:10.1007/s00585-999-1298-4

Cited by 63 publications

(59 citation statements)

References 28 publications

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“…Modelling studies by Sojka and Schunk (1986) indicated that densities might increase by a factor of two above background within a¯ux tube that convected through cusp-precipitation for some 10±15 min. An electron density enhancement within the cusp region, with characteristics consistent with those of a polar patch, was observed by Walker et al (1999) using radio tomography. Auroral observations con®rmed that soft precipitation had played an important role in the creation of this structure at an altitude where the enhanced plasma densities would be expected to have su ciently long lifetimes to preserve the patch in the cross-polar¯ow.…”

Section: Introductionmentioning

confidence: 69%

“…The durations of the enhancements were in broad agreement with those of increases in F-region backscatter observed by the CUTLASS Iceland radar, with the leading edge of the events observed by ESR lagging the onset of those seen by the HF radar by about 3 min. With the likelihood of increased precipitation accompanying the increased backscatter, it is proposed that the polar patches were created by intensi®cations of soft-particle precipitation within the cusp region in-keeping with the conclusion of Walker et al (1999). Whilst it is not possible to be conclusive about the driving mechanism of the temporal variation in the precipitation, it is likely that it is due to temporal magnetospheric changes.…”

Section: Discussionmentioning

confidence: 96%

“…The modelling study of Sojka et al (1994) indicated the presence of patches in all seasons with their occurrence modulated by UT. Pederson et al (1998) observed patch structures on horizontal scales of some 200±300 km using the Sondrestrom incoherent scatter radar, while Walker et al (1999) imaged a patch-like structure of latitudinal dimension some 2.5°using radio tomography.…”

Section: Introductionmentioning

confidence: 99%

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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: 69%

Section: Discussionmentioning

confidence: 96%

Section: Introductionmentioning

confidence: 99%

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

2000

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“…Soft particle precipitation in the cusp region where particles precipitate directly from the magnetosheath can produce polar cap patches that can be convected over the polar cap (e.g., Walker et al, 1999;Oksavik et al, 2006;Goodwin et al, 2015). As a result of plasma transport and particle precipitation, the high-latitude F region ionosphere is nonuniform and highly dynamic.…”

Section: Introductionmentioning

confidence: 99%

An evaluation of International Reference Ionosphere electron density in the polar cap and cusp using EISCAT Svalbard radar measurements

et al. 2016

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Abstract. Incoherent scatter radar measurements are an important source for studies of ionospheric plasma parameters. In this paper the EISCAT Svalbard radar (ESR) long-term database is used to evaluate the International Reference Ionosphere (IRI) model. The ESR started operations in 1996, and the accumulated database up to 2012 thus covers 16 years, giving an overview of the ionosphere in the polar cap and cusp during more than one solar cycle. Data from ESR can be used to obtain information about primary plasma parameters: electron density, electron and ion temperature, and line-ofsight plasma velocity from an altitude of about 50 and up to 1600 km. Monthly averages of electron density and temperature and ion temperature and composition are also provided by the IRI model from an altitude of 50 to 2000 km. We have compared electron density data obtained from the ESR with the predicted electron density from the IRI-2016 model. Our results show that the IRI model in general fits the ESR data well around the F2 peak height. However, the model seems to underestimate the electron density at lower altitudes, particularly during winter months. During solar minimum the model is also less accurate at higher altitudes. The purpose of this study is to validate the IRI model at polar latitudes.

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“…MacDougall, private communication, 2002). They are created either in the sunlit F-region equatorward of the cusp or by precipitation in the cusp and are subsequently convected across the polar cap [Lockwood and Carlson, 1992;Valladares et al, 1994;McEwen et al, 1995;Ma and Schunk, 1997;Walker et al, 1999;Smith et al, 2000]. The patches have been studied by using both ground-based instruments (such as optical imagers [Steele and Cogger, 1996] and radars ) and satellite-based in situ detectors [Coley and Heelis, 1998].…”

Section: Introductionmentioning

confidence: 99%

Interplanetary magnetic field control of polar patch velocity

2003

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[1] Polar patch drift speed and direction have been investigated using oxygen 630 nm images recorded by an all-sky imager at Eureka (89°CGM), Canada over an extended period, January and December 1998. Statistical studies showed that (1) the interplanetary magnetic field (IMF, from the WIND satellite) B z component linearly controls the patch speed when B z is between À7.5 nT and 0 nT. The speed tends to saturate when B z is less than À7.5nT due to nonlinear coupling between the solar wind and the magnetosphere. The average patch speed of 600 m/s is in agreement with results from earlier studies; (2) The IMF B y or the IMF clock angle has a clear control of the patch drift direction as determined by the drift azimuth angle. When jB y j is less than 7.5nT, the drift azimuth angle is linearly and positively correlated with B y . For a large jB y j (>7.5 nT), the positive correlation is replaced by a negative correlated linear relation and the azimuth angle tends to turn towards 180 degrees; that is, the patches drift in an antisunward direction. These IMF B y effects can be qualitatively explained by the northern winter polar ionospheric convection models developed by Weimer [1995] and Hairston and Heelis [1990]. Results from our quantitative study on the IMF control of polar patch speed and drift direction provide constraints for the development of future polar ionospheric convection models.

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On the possible role of cusp/cleft precipitation in the formation of polar-cap patches

Cited by 63 publications

References 28 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

An evaluation of International Reference Ionosphere electron density in the polar cap and cusp using EISCAT Svalbard radar measurements

Interplanetary magnetic field control of polar patch velocity

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