Inter-hemispheric asymmetries in high-latitude electrodynamic forcing and the thermosphere during the October 8–9, 2012, geomagnetic storm: An integrated data–Model investigation

Yu, Huan; Deng, Yue; Zhu, Qingyu; Maute, Astrid; Hairston, M. R.; Waters, C. L.; Sheng, Cheng; Welling, D. T.; López, Ramón

doi:10.3389/fspas.2023.1062265

Cited by 6 publications

(8 citation statements)

References 76 publications

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“…The latter causes an “intersection” of TADs at low latitudes, driving significant density enhancements there (e.g., those seen on the 4th February in Figure 1; Pham et al., 2022). Thus, the asymmetric FACs on the 3rd would produce asymmetric TAD propagation, in agreement with recent modeling work (Hong et al., 2023; Zhu et al., 2023).…”

Section: Resultssupporting

confidence: 90%

The 2022 Starlink Geomagnetic Storms: Global Thermospheric Response to a High‐Latitude Ionospheric Driver

Billett,

Sartipzadeh,

Ivarsen

et al. 2024

Space Weather

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In this study, we present ionospheric observations of field‐aligned currents from AMPERE and the ESA Swarm A satellite, in conjunction with high‐resolution thermospheric density measurements from accelerometers on board Swarm C and GRACE‐FO, for the third and 4 February 2022 geomagnetic storms that led to the loss of 38 Starlink internet satellites. We study the global storm time response of the thermospheric density enhancements, including their decay and latitudinal distribution. We find that the thermospheric density enhances globally in response to high‐latitude energy input from the magnetosphere‐solar wind system and takes at least a full day to recover to pre‐storm density levels. We also find that the greatest density perturbations occur at polar latitudes consistent with the magnetosphere‐ionosphere dayside cusp, and that there appeared to be a saturation of the thermospheric density during the geomagnetic storm on the fourth. Our results highlight the critical importance of high‐latitude ionospheric observations when diagnosing potentially hazardous conditions for low‐Earth‐orbit satellites.

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Section: Resultssupporting

confidence: 90%

The 2022 Starlink Geomagnetic Storms: Global Thermospheric Response to a High‐Latitude Ionospheric Driver

Billett,

Sartipzadeh,

Ivarsen

et al. 2024

Space Weather

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“…However, there remain very limited discussions within the Earth community of potential feedback from the thermosphere back into the magnetosphere. Very recent models have begun to include two‐way interactions between the thermosphere and magnetosphere, and have highlighted that coupling with the thermosphere directly impacts how magnetospheric currents are closed through the high‐latitude ionosphere (Burleigh et al., 2022) and may be a source of significant hemispheric asymmetries in cross‐polar‐cap potential, hemispheric power, and ion convection at Earth (Hong et al., 2023). Notably, as with Jupiter, the extent to which the thermosphere changes the magnetosphere‐ionosphere coupling varies with the position on the planet, with Thayer (2000) predicting stronger effects for longer auroral events, with that reduction occurring most strongly in the dawn sector.…”

Section: Discussionmentioning

confidence: 99%

Asymmetric Ionospheric Jets in Jupiter's Aurora

Wang,

Stallard,

Melin

et al. 2023

JGR Space Physics

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Simultaneous infrared observations of and H2 emissions from Jupiter's northern aurora using the Near Infrared Spectrograph at Keck Observatory were used to measure the ionospheric and thermospheric wind velocities. ions supercorotate near the dawn auroral oval and subcorotate across the dusk sector and in the dawn polar region relative to the planetary rotation rate, broadly in agreement with past observations and models. An anticyclonic vortex is discovered in H2 flows, closely matching the mean magnetospheric subcorotation when the observed magnetospheric flows are averaged azimuthally. In comparing ion and neutral winds, we measure the line‐of‐sight effective ion drift in the neutral reference frame for the first time, revealing two blue‐shifted sunward flows of ∼2 km/s. Observed and H2 emissions overlap with predictions of the Pedersen conductivity layer, suggesting two different regions of the ionosphere: (a) a deep layer, where neutral forces dominate the thermosphere and symmetric breakdown‐in‐corotation currents can close, and (b) a higher layer, where the observed effective ion drift allows dawn‐to‐dusk Pedersen currents within the upper atmosphere, in turn closing asymmetric currents within the magnetosphere. This ionospheric structure aligns well with recent Juno observations of Jupiter's aurora. The detected thermospheric vortex implies the driving of neutral flows by the momentum from the magnetosphere within the thermosphere and deeper in the atmosphere to potentially 20 mbar. Jovian neutral thermosphere might bridge the gap between current observations and modelings and perhaps be significant to the dynamics of aurora on Earth and other outer planets.

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“…The suppression is expected due to the strong gradient in buoyancy frequency profile which inhibits propagation of the waves. Given that hemispheric asymmetries are an interesting contemporary research topic (Ern et al, 2022;Hong et al, 2023;Yan et al, 2021), the exact cause of such climatological differences needs further attention.…”

Section: Discussionmentioning

confidence: 99%

Observations of Mesospheric Gravity Waves Generated by Geomagnetic Activity

Narayanan,

Wright,

Mlynczak

et al. 2024

JGR Space Physics

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Gravity waves (GWs) play an important role in the dynamics and energetics of the mesosphere. Geomagnetic activity is a known source of GWs in the upper atmosphere. However, how deep the effects of geomagnetic activity induced GWs penetrate into the mesosphere remains an open question. We use temperature measurements from the SABER/TIMED instrument between 2002 and 2018 to study the variations of mesospheric GW activity following intense geomagnetic disturbances identified by AE and Dst indices. By considering several case studies, we show for the first time that the GWs forced by geomagnetic activity can propagate down to about 80 km in the high latitude mesosphere. Only regions above 55° latitudes show a clear response. The fraction of cases in which there is an unambiguous enhancement in GW activity following the onset of geomagnetic disturbance is smaller during summer than other seasons. Only about half of the events show an unambiguous increase in GW activity during non‐summer periods and about one quarter of the events in summer show an enhancement in GWs. In addition, we also find that the high latitude mesopause is often seen to descend in altitude following onset of geomagnetic activity in the non‐summer high latitude region.

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Inter-hemispheric asymmetries in high-latitude electrodynamic forcing and the thermosphere during the October 8–9, 2012, geomagnetic storm: An integrated data–Model investigation

Cited by 6 publications

References 76 publications

The 2022 Starlink Geomagnetic Storms: Global Thermospheric Response to a High‐Latitude Ionospheric Driver

The 2022 Starlink Geomagnetic Storms: Global Thermospheric Response to a High‐Latitude Ionospheric Driver

Asymmetric Ionospheric Jets in Jupiter's Aurora

Observations of Mesospheric Gravity Waves Generated by Geomagnetic Activity

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