Equatorial plasma fountain and its effects over three locations: Evidence for an additional layer, the F3 layer

Balan, N.; Bailey, G. J.; Abdu, M. A.; Oyama, K.-I.; Richards, P. G.; MacDougall, J. W.; Batista, I. S.

doi:10.1029/95ja02639

Cited by 160 publications

(173 citation statements)

References 31 publications

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“…A westward electric field drives the F-layer to move downward and causes an increase of the F-peak density and TEC. The downward movement of the F-layer and the resultant increase of NmF2/TEC with westward electric field are the opposite process of the enhanced fountain with eastward electric field, which was termed the reverse fountain by Balan et al (1995Balan et al ( , 1997. Our observations are consistent with the simulations of Balan et al (1995Balan et al ( , 1997.…”

Section: Resultssupporting

confidence: 82%

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Studies of ionospheric F-region response in the Latin American sector during the geomagnetic storm of 21–22 January 2005

et al. 2011

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Abstract. In the present investigation, we have studied the response of the ionospheric F-region in the Latin American sector during the intense geomagnetic storm of 21-22 January 2005. This geomagnetic storm has been considered "anomalous" (minimum Dst reached −105 nT at 07:00 UT on 22 January) because the main storm phase occurred during the northward excursion of the B z component of interplanetary magnetic fields (IMFs). The monthly mean

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Section: Resultssupporting

confidence: 82%

“…The daytime westward electric field after 20:00 UT is most likely to be driven by the disturbance dynamo process and causes a reverse fountain (Balan et al, 1995(Balan et al, , 1997, which can also result in changes of VTEC.…”

Section: Resultsmentioning

confidence: 99%

Studies of ionospheric F-region response in the Latin American sector during the geomagnetic storm of 21–22 January 2005

et al. 2011

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“…The importance of diffusion, electrodynamic drift, and neutral wind on the generation and modulation of the equatorial anomaly in the electron density, N e , the plasma fountain and several fountain related features (an additional layer, a reverse fountain, an equatorial anomaly in vertical ionospheric electron content, a noon bite-out in NmF2, a nighttime increase in N e , plasma bubbles and spread F) were studied by Balan and Bailey (1995) and Balan et al (1997a). In the present work, we investigate the equatorial anomaly characteristics (the equatorial trough, and crest latitudes and magnitudes) from the comparison between the measured and modeled N e and electron temperatures, T e , during 19-21 March 1988, using the new two-dimensional time dependent model of the low-and middle-latitude plasmasphere and ionosphere (Pavlov, 2003), which employs the updated rate coefficients of chemical reactions of ions and the updated N 2 , O 2 , and O photoionization and photoabsorption cross sections.…”

Section: Introductionmentioning

confidence: 99%

Comparison of the measured and modeled electron densities, and electron and ion temperatures in the low-latitude ionosphere during 19-21 March 1988

Павлов

Fukao²,

Kawamura³

2004

Ann. Geophys.

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Abstract.We have presented a comparison between the modeled NmF2 and hmF2, and NmF2 and hmF2 which were observed at the equatorial anomaly crest and close to the geomagnetic equator simultaneously by the Akita, Kokubunji, Yamagawa, Okinawa, Chung-Li, Manila, Vanimo, and Darwin ionospheric sounders and by the middle and upper atmosphere (MU) radar at Shigaraki (34.85 • N, 136.10 • E, Japan) during the 19-21 March 1988 geomagnetically quiet time period at moderate solar activity near approximately the same geomagnetic meridian of 201 • . A comparison between the electron, T e , and ion, T i , temperatures measured by the MU radar and those produced by the model of the ionosphere and plasmasphere is presented for 19-21 March 1988. It is shown that there is a large disagreement between the measured and modeled hmF2 from about 07:00 UT to about 11:00 UT if the equatorial E×B drift given by Scherliess and Fejer (1999) is used. The required equatorial upward E×B drift is weaker from 03:14 UT to 11:14 UT than that given by Scherliess and Fejer (1999) for the studied time period. The required modification of the E×B drift weakens the effect of the fountain in NmF2 bringing the modeled and measured hmF2 and NmF2, into reasonable agreement. The depth of the equatorial NmF2 trough in the calculated NmF2 is approximately consistent with the measured depth if the modified equatorial E×B drift is used. It has been found that the north-south asymmetries in the observed NmF2 and hmF2 about the geomagnetic equator are mainly caused by the asymmetry in the neutral wind about the geomagnetic equator. In the Northern Hemisphere, the meridional neutral wind taken from the HWW90 wind model and the NRLMSISE-00 atomic oxygen density are corrected so that the model results agree with the ionospheric sounders and MU radar observations. A theory of the primary mechanisms causing the latitude dependence of the morning and evening peaks in T e is developed. The latitude dependence of the magnitudes of these peaks in T eCorrespondence to: A. V. Pavlov (pavlov@izmiran.rssi.ru) is interpreted in terms of the corresponding dependence of the electron density. The relative role of the E×B drift and the plasma drift caused by the neutral wind in the formation and the dependence of the magnitudes of the morning and evening electron temperature peaks on the geomagnetic latitude is studied.Key words. Ionosphere (equatorial ionosphere; electric fields and currents; plasma temperature and density; ionosphere-atmosphere interactions; modeling and forecasting)

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“…Simulations carried out by Watanabe et al (1995a) show that maximum in ionization starts developing around the equator at ∼ 10:00 LT and continues until midnight. Balan et al (1997a), from a study of the equatorial plasma fountain and equatorial ionization anomaly in the ionosphere over Jicamarca (77 • E) and Fortaleza (38 • W) using the SUPIM model under magnetically quiet equinoctial conditions of high solar activity, have shown that the EIA is evident up to an altitude of 700 km in the three locations. The EIA is asymmetric about the equator in all the three sectors and has been found to be strongly influenced by the asym- metric neutral winds and displacement of the geographic and geomagnetic equators.…”

Section: Discussionmentioning

confidence: 99%

“…The upward flow of plasma outside the fountain region can cause convergence of plasma above the F-region peak close to the equator leading to the formation of an additional layer F3. Using the SUPIM, Balan et al (1997a) have found that the north-south asymmetries of the equatorial plasma fountain and equatorial anomaly are more dependent upon the displacement of the geomagnetic equator from the geographic equator. Watanabe et al (1995a) had used a time dependent three-dimensional simulation procedure to study the variation of electron and ion temperature and density within ±30 • and 200 km to 1000 km altitude region.…”

Section: Introductionmentioning

confidence: 99%

Theoretical simulation of O+ and H+ densities in the Indian low latitude F-region and comparison with observations

2002

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Abstract. The O + and H + ion density distributions in the Indian low latitude F-region, within ±15 • magnetic latitudes, are simulated using a time dependent model developed on the basis of solution of the plasma continuity equation. The simulated ion densities for solar minimum June and December solstices are then compared with ionosonde observations from the period 1959-1979 and measurements made by the Indian SROSS C2 satellite during 1995-1996 at an altitude of ∼ 500 km. The simulated O + density has a minimum around pre-sunrise hours and a maximum during noontime. H + density is higher at nighttime and lower during the day. The simulations reproduced the well-known equatorial ionization anomaly (EIA) observed in electron density at the peak of the F2-region in the Indian low latitude sector during solar minimum. In situ measurement of O + density by the SROSS C2, however, showed a single peak of ionization around the equator.

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Equatorial plasma fountain and its effects over three locations: Evidence for an additional layer, the F₃ layer

Cited by 160 publications

References 31 publications

Studies of ionospheric F-region response in the Latin American sector during the geomagnetic storm of 21–22 January 2005

Studies of ionospheric F-region response in the Latin American sector during the geomagnetic storm of 21–22 January 2005

Comparison of the measured and modeled electron densities, and electron and ion temperatures in the low-latitude ionosphere during 19-21 March 1988

Theoretical simulation of O<sup>+</sup> and H<sup>+</sup> densities in the Indian low latitude F-region and comparison with observations

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Equatorial plasma fountain and its effects over three locations: Evidence for an additional layer, the F3 layer

Cited by 160 publications

References 31 publications

Studies of ionospheric F-region response in the Latin American sector during the geomagnetic storm of 21–22 January 2005

Studies of ionospheric F-region response in the Latin American sector during the geomagnetic storm of 21–22 January 2005

Comparison of the measured and modeled electron densities, and electron and ion temperatures in the low-latitude ionosphere during 19-21 March 1988

Theoretical simulation of O&lt;sup&gt;+&lt;/sup&gt; and H&lt;sup&gt;+&lt;/sup&gt; densities in the Indian low latitude F-region and comparison with observations

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Equatorial plasma fountain and its effects over three locations: Evidence for an additional layer, the F₃ layer

Theoretical simulation of O<sup>+</sup> and H<sup>+</sup> densities in the Indian low latitude F-region and comparison with observations