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1. The global mapping of electron precipitation and ionospheric conductance from whistler-mode chorus waves

   https://doi.org/10.3389/fspas.2024.1442009  

   Gillespie, Dillon; Connor, Hyunju Kim; Ma, Qianli; Zhang, Xiao-Jia; Shen, Xiao-Chen; Ozturk, Dogacan; Meredith, Nigel P (December 2024, Frontiers in Astronomy and Space Sciences)

   Auroral precipitation is the second major energy source after solar irradiation that ionizes the Earth’s upper atmosphere. Diffuse electron aurora caused by wave-particle interaction in the inner magnetosphere (L < 8) takes over 60% of total auroral energy flux, strongly contributing to the ionospheric conductance and thus to the ionosphere-thermosphere dynamics. This paper quantifies the impact of chorus waves on the diffuse aurora and the ionospheric conductance during quiet, medium, and strong geomagnetic activities, parameterized by AE <100, 100 < AE < 300, and AE > 300, respectively. Using chorus wave statistics and inner-magnetosphere plasma conditions from Timed History Events and Macroscale Interactions during Substorms (THEMIS) observations, we directly derive the energy spectrum of diffuse electron precipitation under quasi-linear theory. We then calculate the height-integrated conductance from the wave-driven aurora spectrum using the electron impact ionization model of Fang et al. (Geophys. Res. Lett., 2010, 37) and the MSIS atmosphere model. By utilizing Fang’s ionization model, the US Naval Research Laboratory Mass Spectrometer and Incoherent Scattar Radar (NRLMSISE-00) model from 2000s for the neutral atmosphere components, and the University of California, Los Angeles (UCLA) Full Diffusion Code, we improve upon the standard generalization of Maxwellian diffuse electron precipitation patterns and their resulting ionosphere conductance. Our study of global auroral precipitation and ionospheric conductance from chorus wave statistics is the first statistical model of its kind. We show that the total electron flux and conductance pattern from our results agree with those of Ovation Prime model over the pre-midnight to post-dawn sector as geomagnetic activity increases. Our study examines the relative contributions of upper band chorus (UBC) and lower band chorus wave (LBC) driven conductance in the ionosphere. We found LBC waves drove diffuse electron precipitation significantly more than UBC waves, however it is possible that THEMIS data may have underestimated the upper chorus band wave observations for magnetic latitudes below 65 $°$. 

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2. Estimating Precipitating Energy Flux, Average Energy, and Hall Auroral Conductance From THEMIS All-Sky-Imagers With Focus on Mesoscales

   https://doi.org/10.3389/fphy.2021.744298  

   Gabrielse, Christine; Nishimura, Toshi; Chen, Margaret; Hecht, James H.; Kaeppler, Stephen R.; Gillies, D. Megan; Reimer, Ashton S.; Lyons, Larry R.; Deng, Yue; Donovan, Eric; et al (October 2021, Frontiers in Physics)

   Recent attention has been given to mesoscale phenomena across geospace (∼10 s km to 500 km in the ionosphere or ∼0.5 R E to several R E in the magnetosphere), as their contributions to the system global response are important yet remain uncharacterized mostly due to limitations in data resolution and coverage as well as in computational power. As data and models improve, it becomes increasingly valuable to advance understanding of the role of mesoscale phenomena contributions—specifically, in magnetosphere-ionosphere coupling. This paper describes a new method that utilizes the 2D array of Time History of Events and Macroscale Interactions during Substorms (THEMIS) white-light all-sky-imagers (ASI), in conjunction with meridian scanning photometers, to estimate the auroral scale sizes of intense precipitating energy fluxes and the associated Hall conductances. As an example of the technique, we investigated the role of precipitated energy flux and average energy on mesoscales as contrasted to large-scales for two back-to-back substorms, finding that mesoscale aurora contributes up to ∼80% (∼60%) of the total energy flux immediately after onset during the early expansion phase of the first (second) substorm, and continues to contribute ∼30–55% throughout the remainder of the substorm. The average energy estimated from the ASI mosaic field of view also peaked during the initial expansion phase. Using the measured energy flux and tables produced from the Boltzmann Three Constituent (B3C) auroral transport code (Strickland et al., 1976; 1993), we also estimated the 2D Hall conductance and compared it to Poker Flat Incoherent Scatter Radar conductance values, finding good agreement for both discrete and diffuse aurora. 

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3. Evolution of Ionospheric Ion Upflow Flux During the April 2023 Geomagnetic Storm

   https://doi.org/10.1029/2025JA034088  

   Kwon, Grace; Zou, Shasha; Hairston, Marc; Sun, Hu; Smirnova, Maria (January 2026, Journal of Geophysical Research: Space Physics)

   Abstract We study the impact of the evolving magnetosphere‐ionosphere‐thermosphere system on upward ion fluxes during the 23–24 April 2023 geomagnetic storm. This storm has a “double‐dip” structure where two southward IMF periods cause two dips in the SYM‐H index. The auroral electrojet indices and field‐aligned currents reveal comparable ionospheric energy inputs during both dips. We use global total electron content maps to track mid‐to‐high‐latitude ionospheric density structures, which are known to have significant effects on upward ion fluxes. We find that each southward turning triggers a positive ionospheric storm phase. However, thermospheric O/N₂depletions initiated during the 1st dip moderate the effects of magnetospheric driving on the ionosphere during the 2nd dip. Consequently, the density structures in the second positive phase are weaker and confined to lower latitudes than before. We use density and velocity measurements from DMSP satellites to identify regions with strong upward ion fluxes. We find that the storm‐enhanced density (SED) plume from the 1st dip drives significant upward fluxes when it crosses the open‐closed field line boundary. Comparable fluxes exist in the dawn sector due to large upward drifts driven by persistent energy inputs under strong negative conditions. We conclude that the evolution of storm‐time ion upflow flux has a local time dependency. The density‐regulated afternoon/evening sector fluxes are seeded by ionospheric high‐density structures and modulated by the thermospheric composition, while the velocity‐regulated dawn/morning sector fluxes are more consistent throughout the storm due to the steady magnetospheric driving under strong negative conditions. 

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4. Continuous Enhancements of Electron Temperature in the Subauroral Ionosphere Over Eight Days During the 2015 St. Patrick’s Day Storm

   https://doi.org/10.1029/2022JA030629  

   Huang, Chao‐Song; Zhang, Yongliang; Wang, Wenbin; Wu, Qian; Lin, Dong (August 2022, Journal of Geophysical Research: Space Physics)

   Abstract We have used measurements of the Defense Meteorological Satellite Program (DMSP) satellites to study variations of electron temperature in the subauroral ionosphere during the magnetic storm on 17–25 March 2015. This magnetic storm had a long recovery phase of 7 days, and the ionospheric behavior over the entire storm time was seldom investigated. In this study, we find that the electron temperature at subauroral latitudes was continuously enhanced for 8 days, from the storm onset to the end of the recovery phase. The maximum electron temperature during the storm times was 1000–4000 K higher than the maximum electron temperature during quiet times. This long‐lasting enhancement of subauroral electron temperature was attributed to energy transfer among the solar wind, magnetosphere, ring current, plasmasphere, and ionosphere driven by high‐speed solar wind streams and fluctuating interplanetary magnetic field during the entire 8‐day period of the storm. The electron temperature enhancements were quite symmetric in the post‐midnight sector but became strongly asymmetric near dawn between the southern and northern hemispheres. The asymmetric enhancements of electron temperature near dawn may be related to the magnetic declination and the daytime midlatitude trough in the southern hemisphere. Large daily variations of maximum electron temperature in the post‐midnight sector were observed and may be related to the offset between geomagnetic and geographic latitudes. These DMSP observations provide new insight on ionospheric response to intense magnetic storms. 

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5. Kinetic Alfven Waves Driving Auroral O+ Ion Outflows to Form Plasma Cloak During the 17 March 2015 Geomagnetic Storm

   https://doi.org/10.1029/2024JA033169  

   Tian, S; Li, J; Wang, C‐P; Ma, Q; Bortnik, J; Ferradas, C P; Liu, J; Shen, Y; Lyons, L R (January 2025, Journal of Geophysical Research: Space Physics)

   Abstract We present multi‐platform observations of plasma cloak, O+ outflows, kinetic Alfven waves (KAWs), and auroral oval for the geomagnetic storm on 17 March 2015. During the storm's main phase, we observed a generally symmetric equatorward motion of the auroral oval in both hemispheres, corresponding to the plasmasphere erosion and inward motion of the plasma sheet. Consequently, Van Allen Probes became immersed within the plasma sheet for extended hours and repeatedly observed correlated KAWs and O+ outflows. The KAWs contain adequate energy flux toward the ionosphere to energize the observed outflow ions. Adiabatic particle tracing suggests that the O+ outflows are directly from the nightside auroral oval and that the energization is through a quasi‐static potential drop. The O+ outflows from the nightside auroral oval were adequate (‐ #/‐s) and prompt (several minutes) to explain the newly formed plasma cloak, suggesting that they were a dominant initial source of plasma cloak during this storm. 

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