The dayside high-latitude trough under quiet geomagnetic conditions: Radio tomography and the CTIP model

Pryse, S. E.; Dewis, K. L.; Middleton, H. R.; Denton, M. H.

doi:10.5194/angeo-23-1199-2005

Cited by 24 publications

(31 citation statements)

References 29 publications

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“…Comparisons of the width of the tongue show that the modeled TOI (in both runs) covers a larger latitude range than that observed, but it must be borne in mind that the latitudinal dimension of the grid cells of the model is 2° while that of the observations is 0.25°. It has been shown in other studies comparing CTIP model output to observations [ Pryse et al , 2005], that the precipitation input is slightly too high and this would account for the differences in densities between the model run which includes the precipitation and the observations. These predictions, along with the EISCAT results lead us to the conclusion that the in situ precipitation played very little part, if any, in the production of the poleward trough wall observed in this case.…”

Section: Discussionmentioning

confidence: 99%

“…Tomography has been used in a recent study to parameterise the location and shape of the trough at midlatitudes over the UK [ Pryse et al , 2006a]. Obviously, both empirical and numerical models are important for predicting the structure of the ionosphere and neither can be used with any reliability if they haven't been verified by comparison with observations [e.g., Pryse et al , 2005].…”

Section: Introductionmentioning

confidence: 99%

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The role of the tongue‐of‐ionization in the formation of the poleward wall of the main trough in the European post‐midnight sector

2008

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[1] A series of radio tomography reconstructions from the University of Wales Aberystwyth receiver chains in Scandinavia and the UK, imaging the midnight-dawn sector on 13 December 2001, reveal a persistent large-scale electron density enhancement, which forms the poleward wall of the main ionization trough. Measurements by the European Incoherent Scatter radar (EISCAT) rule out in situ soft-particle precipitation as the main source of the higher densities. SuperDARN plasma drift observations and electric potential patterns place the feature in the dawn cell of the high-latitude convection, leading to the conclusion that the higher density is likely to have originated as photoionization and was convected over the polar cap to the nightside and around toward dawn in a tongue-of-ionization (TOI). Suitable runs of the Coupled ThermosphereIonosphere-Plasmasphere (CTIP) model support this interpretation and also reveal that the formation of the TOI is heavily UT dependent, which would lead to it being most prominent at nighttime in the European sector.Citation: Middleton, H. R., S. E. Pryse, A. G. Wood, and R. Balthazor (2008), The role of the tongue-of-ionization in the formation of the poleward wall of the main trough in the European post-midnight sector,

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The role of the tongue‐of‐ionization in the formation of the poleward wall of the main trough in the European post‐midnight sector

2008

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“…Although this scale is quite large, smaller structures are expected to develop within these patches [Hosokawa et al, 2009]. Structure also exists in the region of the high-latitude ionospheric trough that, at least on the dayside, can be located poleward of the Hankasalmi SuperDARN radar location [e.g., Sojka et al, 1990;Pryse et al, 2005]. The poleward edge of the trough can produce an increase in electron density by an order of magnitude in a few tens of kilometers [e.g., Mitchell et al, 1995].…”

Section: Measurement Area Discrepanciesmentioning

confidence: 99%

A comparison of EISCAT and SuperDARN F‐region measurements with consideration of the refractive index in the scattering volume

et al. 2010

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[1] Gillies et al. (2009) proposed the use of interferometric measurements of the angle of arrival as a proxy for the scattering region refractive index n s needed to estimate the line-of-sight Doppler velocity of the ionospheric plasma from HF [Super Dual Auroral Radar Network (SuperDARN)] radar observations. This study continues this work by comparing measurements of line-of-sight velocities by SuperDARN with tristatic velocity measurements by the EISCAT incoherent scatter radar from 1995 to 1999. From a statistical viewpoint, velocities measured by SuperDARN were lower than velocities measured by EISCAT. This can, at least partially, be explained by the neglect in the SuperDARN analysis of the lower-than-unity refractive index of the scattering structures. The elevation angle measured by SuperDARN was used as a proxy estimate of n s and this improved the comparison, but the velocities measured by SuperDARN were still lower. Other estimates of n s using electron densities N e based on both EISCAT measurements and International Reference Ionosphere model values did not increase the SuperDARN velocities enough to attain the EISCAT values. It is proposed that dense structures that were of comparable size to the SuperDARN scattering volume partially help resolve the low-velocity issue. These dense, localized structures would provide the N e gradients required for generation of the coherent irregularities from which the SuperDARN radar waves scatter, whereas EISCAT incoherent radar measurements provide only the background N e and not the density of the small-scale structures. The low-velocity SuperDARN results suggest that small-scale dense structures with refractive indices well below unity must exist within the SuperDARN scattering volume and may contribute greatly to the scattering process.

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“…Fuller treatment of the precipitation is outside the scope of this investigation. However, it has a marked effect that needs consideration in future as indicated by Schoendorf et al (1996) and Pryse et al (2005).…”

Section: Comparison Between Model Output and Radiotomography Observatmentioning

confidence: 99%

Modelling the tongue-of-ionisation using CTIP with SuperDARN electric potential input: verification by radiotomography

et al. 2009

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Abstract. Electric potential patterns obtained by the SuperDARN radar network are used as input to the Coupled Thermosphere-Ionosphere-Plasmasphere model, in an attempt to improve the modelling of the spatial distribution of the ionospheric plasma at high latitudes. Two case studies are considered, one under conditions of stable IMF B z negative and the other under stable IMF B z positive. The modelled plasma distributions are compared with sets of wellestablished tomographic reconstructions, which have been interpreted previously in multi-instrument studies. For IMF B z negative both the model and observations show a tongueof-ionisation on the nightside, with good agreement between the electron density and location of the tongue. Under B z positive, the SuperDARN input allows the model to reproduce a spatial plasma distribution akin to that observed. In this case plasma, unable to penetrate the polar cap boundary into the polar cap, is drawn by the convective flow in a tongue-of-ionisation around the periphery of the polar cap.

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The dayside high-latitude trough under quiet geomagnetic conditions: Radio tomography and the CTIP model

Cited by 24 publications

References 29 publications

The role of the tongue‐of‐ionization in the formation of the poleward wall of the main trough in the European post‐midnight sector

The role of the tongue‐of‐ionization in the formation of the poleward wall of the main trough in the European post‐midnight sector

A comparison of EISCAT and SuperDARN F‐region measurements with consideration of the refractive index in the scattering volume

Modelling the tongue-of-ionisation using CTIP with SuperDARN electric potential input: verification by radiotomography

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