Wind dynamo effects on ground magnetic perturbations and vertical drifts

Fang, Tzu‐Wei; Richmond, A. D.; Liu, J. Y.; Maute, Astrid

doi:10.1029/2008ja013513

Cited by 37 publications

(38 citation statements)

References 47 publications

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“…Scherliess and Fejer 1999) Equatorial daytime vertical drifts are also now routinely derived from the difference of horizontal geomagnetic fields measured at pairs of stations, one very near the magnetic equator and another a few degrees off at about the same longitude (e.g., Anderson et al 2002Anderson et al , 2004Shume et al 2009). Vertical drifts derived using magnetic field data from Jicamarca and Piura (5.2°S, 80.6°W; 6.8°magnetic) are generally in good agreement with radar measured 150-km and F region Jicamarca drifts, but their accuracy can sometimes be affected by magnetic field changes produced by variable low latitude E region winds (e.g., Fang et al 2008). Recently, equatorial zonal electric fields have been derived from equatorial magnetic field measurements by the CHAMP satellite (Alken and Maus 2010).…”

Section: Climatology Of Equatorial Plasma Driftsmentioning

confidence: 84%

Low Latitude Ionospheric Electrodynamics

Fejer

2010

Space Sci Rev

134

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The low latitude ionosphere is strongly affected by several highly variable electrodynamic processes. Over the last two decades ground-based and satellite measurements and global numerical models have been extensively used to study the longitude-dependent climatology of low latitude electric fields and currents. These electrodynamic processes and their ionospheric effects exhibit large ranges of temporal and spatial variations during both geomagnetic quiet and disturbed conditions. Numerous recent studies have investigated the short term response of equatorial electric fields and currents to lower atmospheric transport processes and solar wind-magnetosphere driving mechanisms. This includes the large electric field and current perturbations associated with arctic sudden stratospheric warming events during geomagnetic quiet times and highly variable storm time prompt penetration and ionospheric disturbance dynamo effects. In this review, we initially describe recent experimental and numerical modeling results of the global climatology and short term variability of quiet time low latitude electrodynamic plasma drifts. Then, we examine the present understanding of equatorial electric field and current perturbation fields during periods of enhanced geomagnetic activity.

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Section: Climatology Of Equatorial Plasma Driftsmentioning

confidence: 84%

Low Latitude Ionospheric Electrodynamics

Fejer

2010

Space Sci Rev

134

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“…Immel et al (2006) conclude that neutral winds in the lower atmosphere influence and modulate the E-region dynamo to produce spatial variability approximately 1,000 km scales. Other causes of EEJ variability suggested by earlier workers are (i) the variations in tidal strength (Stening 1975) and the sharp longitudinal gradients in the diurnal non-migrating tides (DE2 and DW2) between the longitudes over 15°separation (Anderson et al 2009); (ii) the day to day variability of zonal winds (Fang et al 2008); (iii) the day-to-day variability in semidiurnal tide at lower thermosphere, modulated by interactions at planetary wave periodicities (Fuller-Rowell et al 2008); and (iv) the modulation of ionospheric dynamo in the middle atmosphere through the excitation of solar non-migrating tides in the troposphere (Jin et al 2011).…”

Section: Resultsmentioning

confidence: 99%

Evidence of short spatial variability of the equatorial electrojet at close longitudinal separation

2014

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The characteristics of longitudinal variability of equatorial electrojet (EEJ) and counter electrojet (CEJ), presented in this study, are based on concurrent observations from a hitherto unsampled region of the world to examine the (1) degree of correlation between hourly means and monthly averaged hourly means of ground observations with equatorial electrojet climatological model (EEJM-2.0), (2) day-to-day longitudinal variability of EEJ strength between the pairs of sites, and (3) At both longitudes, the overall correlation of monthly mean hourly values (i.e., from 05:00 to 19:00 LT) between the observed EEJ strength and modeled current density from EEJM-2.0 is good (r > 0.8). However, a significant lack of correlation is witnessed on day-to-day peak values (i.e., 12:00 LT) between the observed variations and the model at both sites. Further, a comparison of noontime peaks between the two sites shows a considerable day-to-day variability. A large number of CEJs (43 events) are recorded during the study: at CBY (15 events) and VEN (28 events). Analyses of the CEJ events highlight the variability of CEJ phenomena in terms of amplitude, dates, and time of occurrence over 15°l ongitude separation. The local nature of perturbations causing CEJ is evident; the possible factors are being non-migrating eastward and westward propagating diurnal tides and local meteorological phenomena associated with upper mesospheric temperature, wind, and density variations.

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“…This suggests that Sq and EEJ are driven by different factors, which could naturally result in a weak correlation between the two. Fang et al (2008) has demonstrated using a Thermosphere Ionosphere Mesosphere Electrodynamic General Circulation Model (TIME-GCM) simulation that local wind could significantly affect the EEJ. We also know that Sq is affected by large-scale global wind, while EEJ is affected by both global and local wind.…”

Section: Discussionmentioning

confidence: 99%

Relationship between the equatorial electrojet and global Sq currents at the dip equator region

et al. 2014

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The equatorial electrojet (EEJ) is a strong eastward ionospheric current flowing in a narrow band along the dip equator. In this study, we examined the EEJ-Sq relationship by using observations at six stations in the South American, Indian, and Southeast Asian sectors. The analysis was carried out with data on geomagnetically quiet days with Kp ≤3 from 2005 to 2011. A normalization approach was used because it yields more accurate results by overcoming the uncertainties due to latitudinal variation of the EEJ and Sq. A weak positive correlation between the EEJ and Sq was obtained in the Southeast Asian sector, while weak negative correlations were obtained in the South American and Indian sectors. EEJ-Sq relationship is found to be independent of the hemispheric configuration of stations used to calculate their magnetic perturbations, and it also only changed slightly during low and moderate solar activity levels. These results demonstrate that the Southeast Asian sector is indeed different from the Indian and South American sectors, which is indicative of unique physical processes particularly related to the electro-dynamo. Furthermore, we also demonstrate that the definition of the EEJ, that is, the total current or enhanced current, can significantly affect the conclusions drawn from EEJ-Sq correlations.

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Wind dynamo effects on ground magnetic perturbations and vertical drifts

Cited by 37 publications

References 47 publications

Low Latitude Ionospheric Electrodynamics

Low Latitude Ionospheric Electrodynamics

Evidence of short spatial variability of the equatorial electrojet at close longitudinal separation

Relationship between the equatorial electrojet and global Sq currents at the dip equator region

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