Solar zenith angle dependencies of F1-layer, &amp;lt;i&amp;gt;Nm&amp;lt;/i&amp;gt;F2 negative disturbance, and G-condition occurrence probabilities

Lobzin, V. V.; Павлов, А. В.

doi:10.5194/angeo-20-1821-2002

Cited by 11 publications

(8 citation statements)

References 48 publications

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“…There are several studies on responses of low latitude ionosphere to magnetic storms events (Sobral et al 1997, Pincheira et al 2002, Abdu 2001, Lobzin and Pavlov 2002aPavlov et al 2004, Lynn et al 2004, Lima et al 2004, Dashora et al 2009, de Siqueira et al 2011, D'ujanga et al 2013. A number of studies by Nigerian researchers have also been conducted on low latitudinal ionosphere responses during magnetic storm periods that have contributed to our understanding on this subject (Adeniyi 1986, Olawepo and Adeniyi 2012, Olawepo 2013, Ariyibi et al 2013a.…”

Section: Introductionmentioning

confidence: 99%

Investigation of Ionospheric Response to Geomagnetic Storms over a Low Latitude Station, Ile-Ife, Nigeria

2016

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Due to several complexities associated with the equatorial ionosphere, and the significant role which the total electron content (TEC) variability plays in GPS signal transmission, there is the need to monitor irregularities in TEC during storm events. The GPS SCINDA receiver data at Ile-Ife, Nigeria, was analysed with a view to characterizing the ionospheric response to geomagnetic storms on 9 March and 1 October 2012. Presently, positive storm effects, peaks in TEC which were associated with prompt penetration of electric fields and changes in neutral gas composition were observed for the storms. The maximum percentage deviation in TEC of about 120 and 45% were observed for 9 March and 1 October 2012, respectively. An obvious negative percentage TEC deviation subsequent to sudden storm commencement (SSC) was observed and besides a geomagnetic storm does not necessarily suggest a high scintillation intensity (S 4) index. The present results show that magnetic storm events at low latitude regions may have an adverse effect on navigation and communication systems.

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Section: Introductionmentioning

confidence: 99%

Investigation of Ionospheric Response to Geomagnetic Storms over a Low Latitude Station, Ile-Ife, Nigeria

2016

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“…However, the electron density of the F 1 layer will not change much with the O/N 2 ratio. As we know, besides O + , the F 1 layer contains molecular ions, such as NO + and O 2 + (Lobzin & Pavlov, , ). This is different from the F 2 layer where the O + ions are dominant.…”

Section: Discussionmentioning

confidence: 99%

“…The N m F 1 is affected by but not determined by the O/N 2 ratio. As a result, the production and chemical loss processes of the F 1 layer are much more complicated than those in the F 2 layer, and the role of the O/N 2 ratio is more important in the F 2 layer (Lobzin & Pavlov, ). It is observed from COSMIC that the electron density of the F 1 layer peak does not change as significantly with longitude as it does in the altitude above at midlatitudes (Figures , , and ).…”

Section: Discussionmentioning

confidence: 99%

“…Furthermore, the local time dependence of the F 1 layer peak occurrence probability varies with latitude and season. For the same solar zenith angle (SZA), the F 1 layer peak occurrence probability is almost the same before and after noon for all seasons at middle latitudes, while it is higher in prenoon than in afternoon for all seasons in the equatorial region (Lobzin & Pavlov, ).…”

Section: Introductionmentioning

confidence: 99%

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Longitudinal Variations of the Occurrence Probability of the Ionospheric F₁ Layer Peak at Middle and High Latitudes

2019

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This study focuses on the longitudinal variations of the ionospheric F 1 layer occurrence probabilities from middle to high latitudes (40-70°) in the daytime in summer under low solar activity conditions. The ionospheric electron density profiles retrieved from the Constellation Observing System for Meteorology, Ionosphere, and Climate observations are used. The patterns of the F 1 layer occurrence probabilities are constructed with latitude, longitude, and local time in both hemispheres. The results illustrate a new feature that the occurrence probability of the F 1 layer changes with longitude in both hemispheres. Specifically, the F 1 layer generally occurs more frequently in the longitudes within~160°E-90°W at 40-70°N and within 0-150°E at 40-70°S. The peak occurrence probabilities occur around 150°W (>0.6) and 60°E (>0.8) in the Northern and Southern Hemispheres, respectively. The valleys with values near 0 are located at about 120°W at 40-70°S. A minor peak (~0.4) also occurs within~0-90°E at 40-70°N. These locations depend on latitude and local time. A simulation using the Thermosphere Ionosphere Electrodynamics General Circulation Model (TIEGCM) reproduces the observed longitudinal pattern well. Further TIEGCM simulations show that the higher F 1 layer occurrence probabilities can be largely explained by longitudinal variations of the O/N 2 ratios and also that the dynamic processes, such as the neutral winds above the F 1 layer, have additional contributions. These results reveal that the low O/N 2 ratios deplete the ionospheric electron density above the F 1 layer at middle and high latitudes and thus makes the F 1 layer stand out.

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“…Here the case when the electron density of the lower peak is greater (see Fig. 3b) than that of the upper peak -the case similar to so called G condition for the mid-latitude ionosphere F region (e.g., see Lobzin and Pavlov, 2002), also occurs for some phase of shear wave. The lifetime of multi-layer structure in the ionosphere F2 region depends on the characteristic time of shear wave existence (t a ¼ 2k y =ak x ), which could be up to 1-3 h (Didebulidze and Pataraya, 1999).…”

Section: Theoretical Simulationmentioning

confidence: 94%

Ionosphere F2 layer stratification caused by shear excited atmospheric vortical perturbation

Didebulidze

Lomidze

Gudadze

2009

Advances in Space Research

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Solar zenith angle dependencies of F1-layer, <i>Nm</i>F2 negative disturbance, and G-condition occurrence probabilities

Cited by 11 publications

References 48 publications

Investigation of Ionospheric Response to Geomagnetic Storms over a Low Latitude Station, Ile-Ife, Nigeria

Investigation of Ionospheric Response to Geomagnetic Storms over a Low Latitude Station, Ile-Ife, Nigeria

Longitudinal Variations of the Occurrence Probability of the Ionospheric F₁ Layer Peak at Middle and High Latitudes

Ionosphere F2 layer stratification caused by shear excited atmospheric vortical perturbation

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Solar zenith angle dependencies of F1-layer, &lt;i&gt;Nm&lt;/i&gt;F2 negative disturbance, and G-condition occurrence probabilities

Cited by 11 publications

References 48 publications

Investigation of Ionospheric Response to Geomagnetic Storms over a Low Latitude Station, Ile-Ife, Nigeria

Investigation of Ionospheric Response to Geomagnetic Storms over a Low Latitude Station, Ile-Ife, Nigeria

Longitudinal Variations of the Occurrence Probability of the Ionospheric F1 Layer Peak at Middle and High Latitudes

Ionosphere F2 layer stratification caused by shear excited atmospheric vortical perturbation

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Product

Resources

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Solar zenith angle dependencies of F1-layer, <i>Nm</i>F2 negative disturbance, and G-condition occurrence probabilities

Longitudinal Variations of the Occurrence Probability of the Ionospheric F₁ Layer Peak at Middle and High Latitudes