Variation of ionospheric slab thickness observations at Chumphon equatorial magnetic location

Kenpankho, Prasert; Supnithi, Pornchai; Tsugawa, Takuya; Maruyama, Takashi

doi:10.5047/eps.2011.03.003

Cited by 18 publications

(9 citation statements)

References 20 publications

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“…Many other studies have reported for different longitudinal sectors that the ionospheric slab thickness also depends on diurnal, seasonal, solar activity, latitudinal and geomagnetic activity variations (e.g. Bhonsle et al, 1965;Titheridge, 1973;Kersley and Hajeb-Hosseinieh, 1976;Bhuyan et al, 1986;Davies and Liu, 1991;Jayachandran et al, 2004;Gulyaeva and Stanislawska, 2005;Kenpankho et al, 2011;Venkatesh et al, 2011). Jayachandran et al (2004) reported an ionosphere more thick during high solar activity when compared to low solar activity period.…”

Section: Introductionmentioning

confidence: 95%

Ionospheric slab thickness at the equatorial anomaly region after the deep solar minimum of cycle 23/24

Duarte-Silva

Muella

Silva

et al. 2015

Advances in Space Research

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Section: Introductionmentioning

confidence: 95%

Ionospheric slab thickness at the equatorial anomaly region after the deep solar minimum of cycle 23/24

Duarte-Silva

Muella

Silva

et al. 2015

Advances in Space Research

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“…EST provides an alternative way to interpret H. Once we have EST, we could estimate H and further the electron density profile. Thus, the spatial, temporal, and solar activity features of EST have been studied worldwide [Breed et al, 1997;Chuo et al, 2010;Dabas et al, 1993;Davies and Liu, 1991;Duarte-Silva et al, 2015;Goodwin et al, 1995aGoodwin et al, , 1995bGulyaeva, 2007;Gulyaeva et al, 2004;Jin et al, 2007;Kenpankho et al, 2011;Kouris et al, 2008;Stankov and Warnant, 2009]. Moreover, geomagnetic storms are also found to influence EST [e.g., Àlàgbé, 2012;Chuo et al, 2010;Gulyaeva, 2007].…”

Section: Introductionmentioning

confidence: 99%

A global picture of ionospheric slab thickness derived from GIM TEC and COSMIC radio occultation observations

et al. 2016

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The ionospheric equivalent slab thickness (EST), defined as the ratio of total electron content (TEC) to F2 layer peak electron density (NmF2), describes the thickness of the ionospheric profile. In this study, we retrieve EST from TEC data obtained from Global Ionospheric Map (GIM) and NmF2 retrieved from Constellation Observing System for Meteorology, Ionosphere and Climate (COSMIC) ionospheric radio occultation data. The diurnal, seasonal, and solar activity variations of global EST are analyzed as the excellent spatial coverage of GIM and COSMIC data. During solstices, daytime EST in the summer hemisphere is larger than that in the winter hemisphere, except in some high‐latitude regions, and the reverse is true for the nighttime EST. The peaks of EST often appear at 0400 local time. The presunrise enhancement in EST appears in all seasons, while the postsunset enhancement in EST is not readily observed in equinox. Both enhancements are attributed to the more remarkable electron density decay of NmF2 compared to that of TEC. The dependence of EST on solar activity is related to the inconsistent solar activity dependences of electron density at different altitudes. Furthermore, it is interesting that EST is enhanced from 0° to 120°E in longitude and 30° to 75°S in latitude during nighttime, just to the east of Weddell Sea Anomaly, during equinox and the Southern Hemisphere summer. This phenomenon is supposed to be related to the effects of geomagnetic declination‐related plasma vertical drifts.

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“…Bhonsle et al, 1965;Titheridge, 1973;Huang, 1983). Based on most of the available and reliable observations of ionospheric TEC and NmF2, numerous analyses for recording the climatology of the slab thickness have been conducted over the past few decades (Jayachandran et al, 2004;Chuo, 2007;Jin et al, 2007;Stankov and Warnant, 2009;Guo et al, 2011;Kenpankho et al, 2011;Weng et al, 2012). Jayachandran et al (2004) investigated the variation in the slab thickness during the solar maximum and minimum phases of an intense solar cycle by using the hourly values of TEC and NmF2 at Hawaii (low latitude), Boulder (mid-latitude) and Goosebay (high latitude).…”

Section: Introductionmentioning

confidence: 99%

Climatology of the ionospheric slab thickness along the longitude of 120° E in China and its adjacent region during the solar minimum years of 2007–2009

Huang

Yuan

2015

Ann. Geophys.

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Abstract. The ionospheric slab thickness is defined as the ratio of the total electron content (TEC) to the ionospheric F2 layer peak electron density (NmF2). In this study, the slab thickness is determined by measuring the ionospheric TEC from dual-frequency Global Positioning System (GPS) data and the NmF2 from the Constellation Observing System for Meteorology, Ionosphere and Climate (COSMIC). A statistical analysis of the diurnal, seasonal and spatial variation in the ionospheric slab thickness is presented along the longitude of 120 • E in China and its adjacent region during the recent solar minimum phase (2007)(2008)(2009). The diurnal ratio, defined as the maximum slab thickness to the minimum slab thickness, and the night-to-day ratio, defined as the slab thickness during daytime to the slab thickness during night-time, are both analysed. The results show that the TEC of the northern crest is greater in winter than in summer, whereas NmF2 is greater in summer than in winter. A pronounced peak of slab thickness occurs during the postmidnight (00:00-04:00 LT) period, when the peak electron density is at the lowest level. A large diurnal ratio exists at the equatorial ionization anomaly, and a large night-to-day ratio occurs near the equatorial latitudes and mid-to high latitudes. It is found that the behaviours of the slab thickness and the F2 peak altitude are well correlated at the latitudes of 30-50 • N and during the period of 10:00-16:00 LT. This current study is useful for improvement of the regional model and accurate calculation of the signal delay of radio waves propagating through the ionosphere.

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Variation of ionospheric slab thickness observations at Chumphon equatorial magnetic location

Cited by 18 publications

References 20 publications

Ionospheric slab thickness at the equatorial anomaly region after the deep solar minimum of cycle 23/24

Ionospheric slab thickness at the equatorial anomaly region after the deep solar minimum of cycle 23/24

A global picture of ionospheric slab thickness derived from GIM TEC and COSMIC radio occultation observations

Climatology of the ionospheric slab thickness along the longitude of 120° E in China and its adjacent region during the solar minimum years of 2007–2009

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