The equatorial ionospheric anomaly in electron content from solar minimum to solar maximum for South East Asia

Walker, G. O.; K., J. H.; Golton, E.

doi:10.1007/s00585-994-0195-0

Cited by 76 publications

(32 citation statements)

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“…On many days, GPS scintillations, TEC depletions, and radar plumes were detected even when the southern crest was absent. The main contributor to the asymmetry of the anomaly is the meridional wind that during the December solstice blows from south to north (Walker et al, 1994). Other factors may be an asymmetrical distribution of the O/N2 ratio or latitudinal gradients of the zonal or vertical neutral wind.…”

Section: Discussionmentioning

confidence: 99%

Latitudinal extension of low-latitude scintillations measured with a network of GPS receivers

et al. 2004

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Abstract.A latitudinal-distributed network of GPS receivers has been operating within Colombia, Peru and Chile with sufficient latitudinal span to measure the absolute total electron content (TEC) at both crests of the equatorial anomaly. The network also provides the latitudinal extension of GPS scintillations and TEC depletions. The GPS-based information has been supplemented with density profiles collected with the Jicamarca digisonde and JULIA power maps to investigate the background conditions of the nighttime ionosphere that prevail during the formation and the persistence of plasma depletions. This paper presents case-study events in which the latitudinal extension of GPS scintillations, the maximum latitude of TEC depletion detections, and the altitude extension of radar plumes are correlated with the location and extension of the equatorial anomaly. Then it shows the combined statistics of GPS scintillations, TEC depletions, TEC latitudinal profiles, and bottomside density profiles collected between September 2001 and June 2002. It is demonstrated that multiple sights of TEC depletions from different stations can be used to estimate the drift of the background plasma, the tilt of the plasma plumes, and in some cases even the approximate time and location of the depletion onset. This study corroborates the fact that TEC depletions and radar plumes coincide with intense levels of GPS scintillations. Bottomside radar traces do not seem to be associated with GPS scintillations. It is demonstrated that scintillations/depletions can occur when the TEC latitude profiles are symmetric, asymmetric or highly asymmetric; this is during the absence of one crest. Comparison of the location of the northern crest of the equatorial anomaly and the maximum latitude of scintillations reveals that for 90% of the days, scintillations are confined within the boundaries of the 50% decay limit of the anomaly crests. The crests of the anomaly are the regions where the most intense GPS scintillations and the deepest TEC depletions are encountered. In accord with early results, we observe that GPS scintillaCorrespondence to: C. E. Valladares (valladar@bc.edu) tions/TEC depletions mainly occur when the altitude of the magnetic equator F-region is above 500 km. Nevertheless, in many instances GPS scintillations and TEC depletions are observed to exist when the F-layer is well below 500 km or to persist when the F-layer undergoes its typical nighttime descent. Close inspection of the TEC profiles during scintillations/depletions events that occur when the equatorial F-layer peak is below 500 km altitude reveals that on these occasions the ratio of the crest-to-equator TEC is above 2, and the crests are displaced 10 • or more from the magnetic equator. When the equatorial F-layer is above 500 km, neither of the two requirements is needed, as the flux tube seems to be inherently unstable. We discuss these findings in terms of the RayleighTaylor instability (RTI) mechanism for flux-tube integrated quantities. We advance the idea that ...

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Section: Discussionmentioning

confidence: 99%

Latitudinal extension of low-latitude scintillations measured with a network of GPS receivers

et al. 2004

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“…The higher "m" values and larger correlation coefficients at high level of significance are also recorded around 19:00-20:00 IST, though the overall EEJ strength around the period (17:00-18:00 IST -before sunset) is observed to be low. The anomaly is fully developed around 13:00-16:00 LT depending on season and solar activity level (Walker et al, 1994). After the development, a decaying trend as well as equatorward movement of the crest follows.…”

Section: Richmondmentioning

confidence: 95%

“…The latitudes of the anomaly crest and strength of the anomaly vary with day, month, season and solar activity as well as with longitudes and wind systems (Rastogi, 1966;Golton and Walker, 1971;Rush and Richmond, 1973;Huang et al, 1989;Walker et al, 1994;Balan and Bailey, 1995). The vertical E×B drift of plasma over the magnetic equator at the F-layer altitude and subsequent diffusion along the magnetic field lines, known as equatorial fountain, generate the EIA.…”

Section: Introductionmentioning

confidence: 99%

“…TEC variability due to EEJ was studied by several groups (Walker and Ma, 1972;Sethia et al, 1980;Balan and Iyer, 1983;Rastogi and Klobuchar, 1990;Walker et al, 1994;Rama Rao et al, 2006). From low latitude region TEC is reported to exhibit a positive correlation with EEJ strength while a negative correlation is reflected from the equatorial stations.…”

Section: Introductionmentioning

confidence: 99%

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Electrojet control of ambient ionization near the crest of the equatorial anomaly in the Indian zone

Chakraborty¹,

Hajra²

2009

Ann. Geophys.

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Abstract. A long-term (1978-1990) database of total electron content (TEC) from a location (Calcutta: 22.58 • N, 88.38 • E geographic, dip: 32 • N) near the northern crest of the equatorial ionization anomaly has extensively been studied to characterize the contribution of fountain effect in the maintenance of ambient ionization. The equatorial electrojet (EEJ) data obtained from ground magnetometer recording are used to assess the contribution of equatorial fountain. Analysis made with instantaneous values, day's maximum values and time-integrated values of EEJ strength exhibit more or less similar features. When instantaneous values of EEJ are considered TEC variations exhibit two maxima in correlation, one around 10:00-12:00 IST and the other around 18:00-20:00 IST. The later maximum in correlation coefficient is conspicuously absent when integrated values of EEJ are considered. An impulse-like feature is reflected in the diurnal TEC variation during the time intervals (09:00-10:00 IST) and (18:00-19:00 IST). The statistical analysis reveals greater correspondence with high level of significance between diurnal TEC and EEJ in the descending epoch of solar cycle than in the ascending one. On the seasonal basis, TEC in the summer solstitial months are observed to be more sensitive to the changes in EEJ strength than in the equinoctial and winter solstitial months. Combining the effects of solar flux, season, local time and EEJ an empirical formula for monthly mean diurnal TEC has been developed and validated using observed TEC data. An estimation of the relative contributions of the several terms appearing in the formula reveals much more solar flux contribution (∼50-70%) in the maintenance of ambient ionization around the present location than the EEJ effects (maximum∼20%).

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“…in Africa, [8]- [13], in South America, [14] [15] [16] [17] [18] over China [19] [20], Huo et al [21] and Perevalova et al [22] over North America, Zakharenkova et al [23] over Japan; Venkatesh et al [24] [25] [26] over Brazil and many more. Ionospheric TEC variations have been investigated in the Indian region, using this data and other separate TEC measurements at Surat [27], Agra [28] and other different stations, namely Trivandrum, Waltair, Raipur and Delhi [6].…”

Section: Introductionmentioning

confidence: 99%

GPS-TEC Variation during Low to High Solar Activity Period (2010-2014) under the Northern Crest of Indian Equatorial Ionization Anomaly Region

Patel¹,

Karia²,

Pathak³

2017

POS

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The measurements of ionospheric TEC (total electron content) are conducted at a low latitude Indian station Surat (21.16˚N, 72.78˚E Geog.), which lies under the northern crest of the equatorial anomaly in Indian region. The data obtained are for a period of five years from low to high solar activity (2010-2014) using GPS (Global Positioning System) receiver. In this study, we report the diurnal and seasonal variation of GPS-TEC, dependence of GPS-TEC with solar activity, geomagnetic condition and EEJ strength. From the seasonal analysis, it is found that greater values of the GPS-TEC are observed during equinox season followed by winter and summer. The appearance (in the year 2011 and 2014) and disappearance (in the year 2010 and 2012) of "winter anomaly" have been observed at the station. From the correlation of GPS-TEC with different solar indices, i.e. solar EUV flux, F10.7 cm solar radio flux and Zurich sunspot number (SSN), it is concluded that the solar index EUV flux is a better controller of GPS-TEC, compared to F10.7 cm and SSN. Further, it is observed that there is no effect of rising solar activity on correlation. Moreover, the percentage variability of GPS-TEC and the standard deviation of GPS-TEC obtained for quiet and disturbed days show that dependence of GPS-TEC on geomagnetic condition is seasonal. Also, there is a positive correlation observed between GPS-TEC and EEJ strength.

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The equatorial ionospheric anomaly in electron content from solar minimum to solar maximum for South East Asia

Cited by 76 publications

References 0 publications

Latitudinal extension of low-latitude scintillations measured with a network of GPS receivers

Latitudinal extension of low-latitude scintillations measured with a network of GPS receivers

Electrojet control of ambient ionization near the crest of the equatorial anomaly in the Indian zone

GPS-TEC Variation during Low to High Solar Activity Period (2010-2014) under the Northern Crest of Indian Equatorial Ionization Anomaly Region

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