Solar quiet current response in the African sector due to a 2009 sudden stratospheric warming event

Multiple observational studies have demonstrated large ionospheric variations during the daytime associated with sudden stratospheric warming (SSW) events, but only limited evidence of ionospheric disturbances during the nighttime has been reported up to now. We focus on the American longitudinal sector with its extensive observational network of Global Navigation Satellite System receivers, four Digisondes located at low and middle latitudes, and the Arecibo and Millstone Hill incoherent scatter radars. The study focuses on a major SSW event of January 2013 to investigate large‐scale disturbances in the nighttime ionosphere. We report a deep decrease in total electron content that reaches a factor of 2–5 as compared to the background level and is observed between local midnight and local sunrise (6–12 UT). This decrease is observed for several consecutive days in the range of latitudes from ~55°S to ~45°N. It is accompanied by a strong downward plasma motion and a significant decrease in ion temperature, as observed by both Arecibo and Millstone Hill radars. These results demonstrate that SSW events cause changes in the nighttime ionosphere that are even larger than in the daytime ionosphere. We discuss variations in electric field and F‐region dynamics as possible drivers of this behavior and suggest that thermospheric winds play a much larger role than previously thought.

Section: Discussionmentioning

confidence: 99%

Deep Ionospheric Hole Created by Sudden Stratospheric Warming in the Nighttime Ionosphere

Гончаренко¹,

Coster²,

Zhang³

et al. 2018

“…The longitudinal dependence of these perturbations at the low-latitude ionosphere during SSW has also been demonstrated by satellite and ground-based measurements (Bolaji et al, 2016;Fejer et al, 2010;Goncharenko et al, 2013;Jonah et al, 2014;Liu et al, 2011;Paes et al, 2014). Using the ground-based magnetometer measurements in the America, Indian, and Pacific equatorial regions during 2002-2003SSW, Fejer et al (2010 showed that morning and afternoon current perturbations are strongest in American sector and weakest (particularly in the afternoon) in the Pacific sector.…”

Section: Introductionmentioning

confidence: 88%

“…Paes et al () pointed out that the EIA suppression is stronger than its intensification in the Brazilian sector during 2008–2009 and 2009–2010 SSW events, which is opposite to the observations over the Peruvian sector. Bolaji et al () observed a reduction in the S q H (solar quite variation of the horizontal magnetic field intensity) magnitude and a reversal in the EEJ in South Africa sector during 2009 SSW, which is largest in the South American sector and smallest in the Central Asian sector.…”

Section: Introductionmentioning

confidence: 99%

Lunar Tidal Modulation of Periodic Meridional Movement of Equatorial Ionization Anomaly Crest During Sudden Stratospheric Warming

Zhang

2018

Using the location of equatorial ionization anomaly (EIA) crest derived from GPS observations in China and Brazilian sector, we investigated the longitudinal dependence of periodic meridional movement of EIA crest during sudden stratospheric warming events in 2003, 2006, and 2009. The solar activity was from high to low for the three events. Results show that the locations of EIA crests in both China and Brazilian sectors exhibit obvious and constant 14‐ to 15‐day periodic oscillation being in‐phase in two sectors, which coincide with the half of the lunar revolution period (29.53 days) and the lunar phase. The temporal extent of wave power at 14–15 days is consistent with the temporal extent of stratospheric zonal wind, indicating that 14‐ to 15‐day periodic meridional movement of EIA crest is due to enhanced lunar tide modulated by zonal wind. In addition, it is also found that the amplitude of 14‐ to 15‐day periodic oscillation of EIA crest in China sector is larger than that in Brazilian sector, which may be caused by the longitudinal variation of tides and neutral wind pattern.

“…The zonal and meridional winds in the mesospheric and lower thermospheric (MLT) region during wintertime are generally eastward and northward over the middle and low latitudes, respectively. However, the SSW can significantly affect the variations of dynamical structures in the MLT region (Chandran et al, 2013; Hoffmann et al, 2007; Ma et al, 2017; Wit et al, 2015) and even in the ionosphere (Bolaji et al, 2016; Owolabi et al, 2019; Siddiqui et al, 2015; Yamazaki et al, 2012). The neutral winds after the onset of SSW are observed to reverse to westward and southward (Chen et al, 2012; Dowdy et al, 2007; Lima et al, 2012; Sathishkumar & Sridharan, 2009; Wang & Alexander, 2009; Yuan et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Variations of Mesospheric Neutral Winds and Tides Observed by a Meteor Radar Chain Over China During the 2013 Sudden Stratospheric Warming

Luan

Lei

et al. 2020

Self Cite

The neutral winds in the mesospheric and lower thermospheric region obtained from a meteor radar chain within the latitudinal range of 18-53°N were decomposed to examine the latitudinal structures of the tides and mean winds during the sudden stratospheric warming (SSW) event in 2013. The zonal wind reversed from eastward to westward and the westward wind was larger at middle latitudes than that at low latitudes during the SSW. Meanwhile, a sharp increase in the northward wind was noticeable at all stations. The amplitudes of the diurnal and semidiurnal tides decreased from 5 to 13 January and increased subsequently. At the same time, the terdiurnal tides increased in amplitude, especially at Beijing, Wuhan, and Kunming, in response to the SSW. Moreover, the tidal phases showed a large shift that corresponded to a great increase in tidal wavelengths in the semidiurnal and terdiurnal components. The wavelet analysis further revealed that the quasi 6-day wave oscillations dominated in the winds at Kunming and Sanya stations, as well as the quasi 16-day wave dominated in the zonal wind, and the quasi 11-day and 16-day waves were prevailing in the meridional winds at Beijing and Wuhan. In the same vein, the quasi 16-day and quasi 11-day waves were prominent in the zonal and meridional winds during 1-18 January at Mohe. Therefore, the tide-planetary wave interactions played a significant role in modulating the behaviors of the mesospheric and lower thermospheric dynamics during the SSW event.LI ET AL.6 of 16 SSW, the structure of daily variabilities was similar at Beijing, Wuhan, Kunming, and Sanya. However, during the 2013 SSW, the semidiurnal amplitude in the zonal wind decreased over Mohe, Beijing, and Wuhan. It decreased further after~9 days and returned to its normal value at around 17 January over Mohe and Beijing. Whereas the semidiurnal amplitude in the zonal wind decreased before the SSW onset and increased during the SSW onset below 90 km at Kunming and below 94 km at Sanya. The variations of semidiurnal amplitude of the zonal wind before and after the 2013 SSW onset were small at all stations. Overall, there were significant fluctuations in the zonal semidiurnal tides over Wuhan, Kunming, and Sanya.The semidiurnal amplitude of the meridional wind was comparable with that of the zonal wind over Mohe. From Wuhan to Sanya, the semidiurnal amplitude of the meridional wind decreased as the latitude decreased. A similar reduction was observed at all stations during the 2013 SSW. Specifically, the reduction of semidiurnal amplitude