Dexin Ren scite author profile

In this study, multiple data sets from Beidou geostationary orbit satellites total electron contents (TECs), ionosonde, meteor radar, magnetometer, and model simulations have been used to investigate the ionospheric responses in the Asian‐Australian sector during the September 2017 geomagnetic storm. It was found that long‐duration daytime TEC enhancements that lasted from 7 to 12 September 2017 were observed by the Beidou geostationary orbit satellite constellation. This is a unique event as the prominent TEC enhancements persisted during the storm recovery phase when geomagnetic activity became quiet. The Thermosphere‐Ionosphere Electrodynamics Global Circulation Model predicted that the TEC enhancements on 7–9 September were associated with the geomagnetic activity, but it showed significant electron density depletions on 10 and 11 September in contrast to the observed TEC enhancements. Our results suggested that the observed long‐duration TEC enhancements from 7 to 12 September are mainly associated with the interplay of ionospheric dynamics and electrodynamics. Nevertheless, the root causes for the observed TEC enhancements seen in the storm recovery phase are unknown and require further observations and model studies.

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Does the Peak Response of the Ionospheric F₂ Region Plasma Lag the Peak of 27‐Day Solar Flux Variation by Multiple Days?

Ren

Lei

Wang

et al. 2018

JGR Space Physics

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In this study, the in situ electron density measurements from the Challenging Minisatellite Payload (CHAMP) and solar extreme ultraviolet (EUV) radiation from the Solar Extreme Ultraviolet Experiment instrument on board the Thermosphere Ionosphere Mesosphere Energetic and Dynamics satellite, both with a time resolution of 1.5 hr, are used to explore the peak response of the ionospheric F2 region plasma to the peak of 27‐day solar EUV flux variation. The time delays of in situ electron density changes obtained from the CHAMP satellite in response to 27‐day solar EUV flux changes vary from 0 to about 3 days. Meanwhile, the Thermosphere Ionosphere Electrodynamics General Circulation Model simulations driven by the measured EUV flux and the actual geomagnetic activity show similar time delays as those observed in the CHAMP measurements. Further simulations reveal that the geomagnetic activity greatly affects the determination of the ionospheric time delay to the 27‐day solar EUV flux variations. Besides, the solar zenith angle change within the solar rotation interval can cause large latitudinal differences in the time delay. The ionospheric time delay to the pure 27‐day solar EUV flux variation is less than 1 day and slightly increases with latitude, when geomagnetic activity and seasonal variations are eliminated in the simulation. The simulation results further suggest that the ionospheric response time is associated with the photochemical, dynamic, and electrodynamic processes in the ionosphere‐thermosphere system.

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Unveiling the Space Weather During the Starlink Satellites Destruction Event on 4 February 2022

Dang

Luo

et al. 2022

Space Weather

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Prediction of the thermospheric and ionospheric responses to the 21 June 2020 annular solar eclipse

Dang

Lei

Wang

et al. 2020

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Key Points:We present a quantitative prediction of the ionosphere-thermosphere responses to the upcoming 21 June 2020 solar eclipse from model simulations q A prominent total electron content (TEC) enhancement occurs in the equatorial ionization anomaly (EIA) region even when the region is still in the shadow of the eclipse q The increase in TEC in the EIA region is caused by changes in the wind transequatorial transport of plasma induced by the eclipse q Citation: . (2020). Prediction of the thermospheric and ionospheric responses to the 21 June 2020 annular solar eclipse. Earth Planet. Phys., 4(3), 231-237. http://doi.Abstract: On 21 June 2020, an annular solar eclipse will traverse the low latitudes from Africa to Southeast Asia. The highest latitude of the maximum eclipse obscuration is approximately 30°. This low-latitude solar eclipse provides a unique and unprecedented opportunity to explore the impact of the eclipse on the low-latitude ionosphere-thermosphere (I-T) system, especially in the equatorial ionization anomaly region. In this study, we describe a quantitative prediction of the impact of this upcoming solar eclipse on the I-T system by using Thermosphere-Ionosphere-Electrodynamics General Circulation Model simulations. A prominent total electron content (TEC) enhancement of around 2 TEC units occurs in the equatorial ionization anomaly region even when this region is still in the shadow of the eclipse. This TEC enhancement lasts for nearly 4.5 hours, long after the solar eclipse has ended. Further model control simulations indicate that the TEC increase is mainly caused by the eclipse-induced transequatorial plasma transport associated with northward neutral wind perturbations, which result from eclipse-induced pressure gradient changes. The results illustrate that the effect of the solar eclipse on the I-T system is not transient and linear but should be considered a dynamically and energetically coupled system.

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Dexin Ren

Was Magnetic Storm the Only Driver of the Long‐Duration Enhancements of Daytime Total Electron Content in the Asian‐Australian Sector Between 7 and 12 September 2017?

Does the Peak Response of the Ionospheric F₂ Region Plasma Lag the Peak of 27‐Day Solar Flux Variation by Multiple Days?

Unveiling the Space Weather During the Starlink Satellites Destruction Event on 4 February 2022

Prediction of the thermospheric and ionospheric responses to the 21 June 2020 annular solar eclipse

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Dexin Ren

Was Magnetic Storm the Only Driver of the Long‐Duration Enhancements of Daytime Total Electron Content in the Asian‐Australian Sector Between 7 and 12 September 2017?

Does the Peak Response of the Ionospheric F2 Region Plasma Lag the Peak of 27‐Day Solar Flux Variation by Multiple Days?

Unveiling the Space Weather During the Starlink Satellites Destruction Event on 4 February 2022

Prediction of the thermospheric and ionospheric responses to the 21 June 2020 annular solar eclipse

Contact Info

Product

Resources

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Does the Peak Response of the Ionospheric F₂ Region Plasma Lag the Peak of 27‐Day Solar Flux Variation by Multiple Days?