Identification of potential precursors for the occurrence of Large-Scale Traveling Ionospheric Disturbances in a case study during September 2017

Ferreira, Arthur Amaral; Borries, Claudia; Xiong, Chao; Borges, Renato Alves; Mielich, Jens; Kouba, Daniel

doi:10.1051/swsc/2020029

Cited by 14 publications

(7 citation statements)

References 65 publications

(92 reference statements)

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“…The passage of LSTIDs in low and middle latitudes generates radio waves scattering, shown as spread F and spread Es in Figures 3-5. However, it should be noted that TIDs/AGWs during the recovery phase of the storm might mix multiple scales of TIDs/AGWs in low and middle latitudes, including the residual largescale TIDs generated in the main phase period [31,59,60], medium-scale and small-scale TIDs originated from the local lower atmosphere, especially at the ZHY station where gravity waves are abundant [61]. During the storm, atmosphere disturbances are violent and often accompanied by atmospheric convection.…”

Section: Discussionmentioning

confidence: 99%

Ionosonde Observations of Spread F and Spread Es at Low and Middle Latitudes during the Recovery Phase of the 7–9 September 2017 Geomagnetic Storm

Wei

Jiang

et al. 2021

Remote Sensing

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This study presents observations of nighttime spread F/ionospheric irregularities and spread Es at low and middle latitudes in the South East Asia longitude of China sectors during the recovery phase of the 7–9 September 2017 geomagnetic storm. In this study, multiple observations, including a chain of three ionosondes located about the longitude of 100° E, Swarm satellites, and Global Navigation Satellite System (GNSS) ROTI maps, were used to study the development process and evolution characteristics of the nighttime spread F/ionospheric irregularities at low and middle latitudes. Interestingly, spread F and intense spread Es were simultaneously observed by three ionosondes during the recovery phase. Moreover, associated ionospheric irregularities could be observed by Swarm satellites and ground-based GNSS ionospheric TEC. Nighttime spread F and spread Es at low and middle latitudes might be due to multiple off-vertical reflection echoes from the large-scale tilts in the bottom ionosphere. In addition, we found that the periods of the disturbance ionosphere are ~1 h at ZHY station, ~1.5 h at LSH station and ~1 h at PUR station, respectively. It suggested that the large-scale tilts in the bottom ionosphere might be produced by LSTIDs (Large scale Traveling Ionospheric Disturbances), which might be induced by the high-latitude energy inputs during the recovery phase of this storm. Furthermore, the associated ionospheric irregularities observed by satellites and ground-based GNSS receivers might be caused by the local electric field induced by LSTIDs.

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Section: Discussionmentioning

confidence: 99%

Ionosonde Observations of Spread F and Spread Es at Low and Middle Latitudes during the Recovery Phase of the 7–9 September 2017 Geomagnetic Storm

Wei

Jiang

et al. 2021

Remote Sensing

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“…To derive oscillational features of TIDs, high‐pass or band‐pass filtering of VTEC can be used. Previous studies used moving average (Borries et al., 2023; Ferreira et al., 2020; Zakharenkova et al., 2016), polynomial fits (Ding et al., 2007; Habarulema et al., 2015; Nykiel et al., 2017), or other estimations of background TEC or trends (Hernández‐Pajares et al., 2006). All these methods give similar results without any significant differences.…”

Section: Methodsmentioning

confidence: 99%

Large‐Scale Traveling Ionospheric Disturbances Over the European Sector During the Geomagnetic Storm on March 23–24, 2023: Energy Deposition in the Source Regions and the Propagation Characteristics

Nykiel,

Ferreira,

Günzkofer

et al. 2024

JGR Space Physics

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Multiple Large‐Scale Traveling Ionospheric Disturbances (LSTIDs) are observed in the European sector in both day‐time and night‐time during the magnetic storm on March 23–24, 2023. The Total Electron Content (TEC) observation from a network of GNSS receivers shows the propagation of LSTIDs with amplitudes between around 0.5 and 1 TECU originating from auroral and polar cusp regions down to southern Europe (35°N) with velocities between around 500 and 1,600 [m/s]. We study the energy deposition to the LSTIDs in the source regions and the resulting horizontal propagation over storm‐time background density by using continuous measurements of EISCAT incoherent scatter radars in northern Norway and Svalbard that allow for estimating the source energy to the thermosphere‐ionosphere system via Joule heating and particle precipitation. Both EISCAT and GNSS TEC data show that the electron density decreased to 50% in the auroral zone after the storm onset. The ionospheric heating caused a nearly 250% increase in the electron temperature above 200 km altitude and the ion temperature above 100 km altitude. We find that Joule Heating acts as a primary energy source for the night‐time LSTIDs triggered in the auroral region, while the day‐time LSTIDs can be also driven by precipitating particles in the polar cusp. We also find that a significant background density decrease over the whole European sector is caused by this storm for the following day, during which almost no clear LSTIDs are observed.

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“…Ionospheric anomalies occur during extreme solar events (solar flares and particle ejections) and magnetic storms. They cause serious malfunctions in the operation of modern ground and space technical equipment [42]. An important parameter characterizing the state of the ionosphere is the critical frequency of the ionospheric F2-layer (foF2).…”

Section: Modeling Of Ionospheric Parameter Time Seriesmentioning

confidence: 99%

Hybrid Model for Time Series of Complex Structure with ARIMA Components

2021

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A hybrid model for the time series of complex structure (HMTS) was proposed. It is based on the combination of function expansions in a wavelet series with ARIMA models. HMTS has regular and anomalous components. The time series components, obtained after expansion, have a simpler structure that makes it possible to identify the ARIMA model if the components are stationary. This allows us to obtain a more accurate ARIMA model for a time series of complicated structure and to extend the area for application. To identify the HMTS anomalous component, threshold functions are applied. This paper describes a technique to identify HMTS and proposes operations to detect anomalies. With the example of an ionospheric parameter time series, we show the HMTS efficiency, describe the results and their application in detecting ionospheric anomalies. The HMTS was compared with the nonlinear autoregression neural network NARX, which confirmed HMTS efficiency.

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Identification of potential precursors for the occurrence of Large-Scale Traveling Ionospheric Disturbances in a case study during September 2017

Cited by 14 publications

References 65 publications

Ionosonde Observations of Spread F and Spread Es at Low and Middle Latitudes during the Recovery Phase of the 7–9 September 2017 Geomagnetic Storm

Ionosonde Observations of Spread F and Spread Es at Low and Middle Latitudes during the Recovery Phase of the 7–9 September 2017 Geomagnetic Storm

Large‐Scale Traveling Ionospheric Disturbances Over the European Sector During the Geomagnetic Storm on March 23–24, 2023: Energy Deposition in the Source Regions and the Propagation Characteristics

Hybrid Model for Time Series of Complex Structure with ARIMA Components

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