Equatorial Ionospheric Disturbance Field-Aligned Plasma Drifts Observed by C/NOFS

Ruilong Zhang; Libo Liu; N. Balan; Huijun Le; Yiding Chen; Biqiang Zhao

doi:10.1029/2018ja025273

Satellite studies of mid- and low-latitude ionospheric disturbance zonal plasma drifts

Geophysical Research Letters ◽

10.1029/98gl01032 ◽

1998 ◽

Vol 25 (9) ◽

pp. 1503-1506 ◽

Cited By ~ 24

Author(s):

Ludger Scherliess ◽

Bela G. Fejer

Keyword(s):

Ionospheric Disturbance ◽

Low Latitude ◽

Plasma Drifts

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The Storm Time Evolution of the Ionospheric Disturbance Plasma Drifts

Journal of Geophysical Research Space Physics ◽

10.1002/2017ja024637 ◽

2017 ◽

Vol 122 (11) ◽

pp. 11,665-11,676 ◽

Cited By ~ 11

Author(s):

Ruilong Zhang ◽

Libo Liu ◽

Huijun Le ◽

Yiding Chen ◽

Jiawei Kuai

Keyword(s):

Time Evolution ◽

Ionospheric Disturbance ◽

Plasma Drifts

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Localization of the source of ionospheric disturbance generated during an earthquake

International Journal of Geomagnetism and Aeronomy ◽

10.1029/2004gi000092 ◽

2006 ◽

Vol 6 (2) ◽

Cited By ~ 19

Author(s):

E. L. Afraimovich ◽

E. I. Astafieva ◽

V. V. Kirushkin

Keyword(s):

Ionospheric Disturbance

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Investigation of Low Latitude Spread-F Triggered by Nighttime Medium-Scale Traveling Ionospheric Disturbance

Remote Sensing ◽

10.3390/rs13050945 ◽

2021 ◽

Vol 13 (5) ◽

pp. 945

Author(s):

Zhongxin Deng ◽

Rui Wang ◽

Yi Liu ◽

Tong Xu ◽

Zhuangkai Wang ◽

...

Keyword(s):

Ionospheric Disturbance ◽

Phase Speed ◽

Morphological Processing ◽

Wave Number ◽

Occurrence Rate ◽

Electron Content ◽

Low Latitude ◽

Total Electron ◽

Medium Scale ◽

Spread F

In the current study, we investigated the mechanism of medium-scale traveling ionospheric disturbance (MSTID) triggering spread-F in the low latitude ionosphere using ionosonde observation and Global Navigation Satellite System-Total Electron Content (GNSS-TEC) measurement. We use a series of morphological processing techniques applied to ionograms to retrieve the O-wave traces automatically. The maximum entropy method (MEM) was also utilized to obtain the propagation parameters of MSTID. Although it is widely acknowledged that MSTID is normally accompanied by polarization electric fields which can trigger Rayleigh–Taylor (RT) instability and consequently excite spread-F, our statistical analysis of 13 months of MSTID and spread-F occurrence showed that there is an inverse seasonal occurrence rate between MSTID and spread-F. Thus, we assert that only MSTID with certain properties can trigger spread-F occurrence. We also note that the MSTID at night has a high possibility to trigger spread-F. We assume that this tendency is consistent with the fact that the polarization electric field caused by MSTID is generally the main source of post-midnight F-layer instability. Moreover, after thorough investigation over the azimuth, phase speed, main frequency, and wave number over the South America region, we found that the spread-F has a tendency to be triggered by nighttime MSTID, which is generally characterized by larger ΔTEC amplitudes.

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Multi-Scale Ionospheric Anomalies Monitoring and Spatio-Temporal Analysis during Intense Storm

Atmosphere ◽

10.3390/atmos12020215 ◽

2021 ◽

Vol 12 (2) ◽

pp. 215

Author(s):

Na Cheng ◽

Shuli Song ◽

Wei Li

Keyword(s):

Magnetic Storm ◽

Large Scale ◽

Temporal Dynamics ◽

Ionospheric Disturbance ◽

Ionospheric Scintillation ◽

Small Scale ◽

Electron Content ◽

Total Electron ◽

Multi Scale ◽

Intense Storm

The ionosphere is a significant component of the geospace environment. Storm-induced ionospheric anomalies severely affect the performance of Global Navigation Satellite System (GNSS) Positioning, Navigation, and Timing (PNT) and human space activities, e.g., the Earth observation, deep space exploration, and space weather monitoring and prediction. In this study, we present and discuss the multi-scale ionospheric anomalies monitoring over China using the GNSS observations from the Crustal Movement Observation Network of China (CMONOC) during the 2015 St. Patrick’s Day storm. Total Electron Content (TEC), Ionospheric Electron Density (IED), and the ionospheric disturbance index are used to monitor the storm-induced ionospheric anomalies. This study finally reveals the occurrence of the large-scale ionospheric storms and small-scale ionospheric scintillation during the storm. The results show that this magnetic storm was accompanied by a positive phase and a negative phase ionospheric storm. At the beginning of the main phase of the magnetic storm, both TEC and IED were significantly enhanced. There was long-duration depletion in the topside ionospheric TEC during the recovery phase of the storm. This study also reveals the response and variations in regional ionosphere scintillation. The Rate of the TEC Index (ROTI) was exploited to investigate the ionospheric scintillation and compared with the temporal dynamics of vertical TEC. The analysis of the ROTI proved these storm-induced TEC depletions, which suppressed the occurrence of the ionospheric scintillation. To improve the spatial resolution for ionospheric anomalies monitoring, the regional Three-Dimensional (3D) ionospheric model is reconstructed by the Computerized Ionospheric Tomography (CIT) technique. The spatial-temporal dynamics of ionospheric anomalies during the severe geomagnetic storm was reflected in detail. The IED varied with latitude and altitude dramatically; the maximum IED decreased, and the area where IEDs were maximum moved southward.

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Co-Seismic Ionospheric Disturbance with Alaska Strike-Slip Mw7.9 Earthquake on 23 January 2018 Monitored by GPS

Atmosphere ◽

10.3390/atmos12010083 ◽

2021 ◽

Vol 12 (1) ◽

pp. 83

Author(s):

Yongming Zhang ◽

Xin Liu ◽

Jinyun Guo ◽

Kunpeng Shi ◽

Maosheng Zhou ◽

...

Keyword(s):

Fault Location ◽

Ionospheric Disturbance ◽

Near Field ◽

Singular Spectrum Analysis ◽

Maximum Amplitude ◽

Strike Slip ◽

Ionospheric Disturbances ◽

Total Electron ◽

Total Electron Contents ◽

Alaska Earthquake

The Mw7.9 Alaska earthquake at 09:31:40 UTC on 23 January 2018 occurred as the result of strike slip faulting within the shallow lithosphere of the Pacific plate. Global positioning system (GPS) data were used to calculate the slant total electron contents above the epicenter. The singular spectrum analysis (SSA) method was used to extract detailed ionospheric disturbance information, and to monitor the co-seismic ionospheric disturbances (CIDs) of the Alaska earthquake. The results show that the near-field CIDs were detected 8–12 min after the main shock, and the typical compression-rarefaction wave (N-shaped wave) appeared. The ionospheric disturbances propagate to the southwest at a horizontal velocity of 2.61 km/s within 500 km from the epicenter. The maximum amplitude of CIDs appears about 0.16 TECU (1TECU = 1016 el m−2) near the epicenter, and gradually decreases with the location of sub-ionospheric points (SIPs) far away from the epicenter. The attenuation rate of amplitude slows down as the distance between the SIPs and the epicenter increases. The direction of the CIDs caused by strike-slip faults may be affected by the horizontal direction of fault slip. The propagation characteristics of the ionospheric disturbance in the Alaska earthquake may be related to the complex conditions of focal mechanisms and fault location.

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Equatorial ionospheric disturbance observed through a transequatorial HF propagation experiment

Annales Geophysicae ◽

10.5194/angeo-24-1401-2006 ◽

2006 ◽

Vol 24 (5) ◽

pp. 1401-1409 ◽

Cited By ~ 12

Author(s):

T. Maruyama ◽

M. Kawamura

Keyword(s):

Large Scale ◽

Ionospheric Disturbance ◽

Great Circle ◽

Rate Of Change ◽

Spatial Distance ◽

Propagation Path ◽

Multiple Signal Classification ◽

Radio Broadcasting ◽

Equatorial Plasma Bubbles ◽

Propagation Experiment

Abstract. A transequatorial radio-wave propagation experiment at shortwave frequencies (HF-TEP) was done between Shepparton, Australia, and Oarai, Japan, using the radio broadcasting signals of Radio Australia. The receiving facility at Oarai was capable of direction finding based on the MUSIC (Multiple Signal Classification) algorithm. The results were plotted in azimuth-time diagrams (AT plots). During the daytime, the propagation path was close to the great circle connecting Shepparton and Oarai, thus forming a single line in the AT plots. After sunset, off-great-circle paths, or satellite traces in the AT plot, often appeared abruptly to the west and gradually returned to the great circle direction. However, there were very few signals across the great circle to the east. The off-great-circle propagation was very similar to that previously reported and was attributed to reflection by an ionospheric structure near the equator. From the rate of change in the direction, we estimated the drift velocity of the structure to range mostly from 100 to 300 m/s eastward. Multiple instances of off-great-circle propagation with a quasi-periodicity were often observed and their spatial distance in the east-west direction was within the range of large-scale traveling ionospheric disturbances (LS-TIDs). Off-great-circle propagation events were frequently observed in the equinox seasons. Because there were many morphological similarities, the events were attributed to the onset of equatorial plasma bubbles.

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A study of atmospheric gravity waves and travelling ionospheric disturbances at equatorial latitudes

Annales Geophysicae ◽

10.1007/s00585-997-1048-4 ◽

1997 ◽

Vol 15 (8) ◽

pp. 1048-1056 ◽

Cited By ~ 41

Author(s):

R. L. Balthazor ◽

R. J. Moffett

Keyword(s):

Gravity Waves ◽

Large Scale ◽

Ionospheric Disturbance ◽

Magnetic Equator ◽

Ionospheric Disturbances ◽

Atmospheric Gravity Waves ◽

Opposite Hemisphere ◽

Travelling Ionospheric Disturbances ◽

F Region ◽

Atmospheric Gravity

Abstract. A global coupled thermosphere-ionosphere-plasmasphere model is used to simulate a family of large-scale imperfectly ducted atmospheric gravity waves (AGWs) and associated travelling ionospheric disturbances (TIDs) originating at conjugate magnetic latitudes in the north and south auroral zones and subsequently propagating meridionally to equatorial latitudes. A 'fast' dominant mode and two slower modes are identified. We find that, at the magnetic equator, all the clearly identified modes of AGW interfere constructively and pass through to the opposite hemisphere with unchanged velocity. At F-region altitudes the 'fast' AGW has the largest amplitude, and when northward propagating and southward propagating modes interfere at the equator, the TID (as parameterised by the fractional change in the electron density at the F2 peak) increases in magnitude at the equator. The amplitude of the TID at the magnetic equator is increased compared to mid-latitudes in both upper and lower F-regions with a larger increase in the upper F-region. The ionospheric disturbance at the equator persists in the upper F-region for about 1 hour and in the lower F-region for 2.5 hours after the AGWs first interfere, and it is suggested that this is due to enhancements of the TID by slower AGW modes arriving later at the magnetic equator. The complex effects of the interplays of the TIDs generated in the equatorial plasmasphere are analysed by examining neutral and ion winds predicted by the model, and are demonstrated to be consequences of the forcing of the plasmasphere along the magnetic field lines by the neutral air pressure wave.

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