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1. A statistical study of space hurricanes in the Northern Hemisphere

   https://doi.org/10.3389/fspas.2022.1047982  

   Lu, Sheng; Xing, Zan-Yang; Zhang, Qing-He; Zhang, Yong-Liang; Ma, Yu-Zhang; Wang, Xiang-Yu; Oksavik, Kjellmar; Lyons, L. R.; Nanan, Balan; Liu, Jing; et al (November 2022, Frontiers in Astronomy and Space Sciences)

   The space hurricane is a newly discovered large-scale three-dimensional magnetic vortex structure that spans the polar ionosphere and magnetosphere. At the height of the ionosphere, it has a strong circular horizontal plasma flow with a nearly zero-flow center and a coincident cyclone-shaped aurora caused by strong electron precipitation associated with intense upward magnetic field-aligned currents. By analyzing the long-term optical observation onboard the Defense Meteorological Satellite Program (DMSP) F16 satellite from 2005 to 2016, we found that space hurricanes in the Northern Hemisphere occur in summer and have a maximum occurrence rate in the afternoon sector around solar maximum. In particular, space hurricanes are more likely to occur in the dayside polar cap at magnetic latitudes greater than 80°, and their MLT (magnetic local time) dependence shows a positive relationship with the IMF (interplanetary magnetic field) clock angle. We also found that space hurricanes occur mainly under dominant positive IMF By and Bz and negative Bx conditions. It is suggested that the stable high-latitude lobe reconnection, which occurs under the conditions of a large Earth’s dipole tilt angle and high ionosphere conductivity in summer, should be the formation mechanism of space hurricanes. The result will give a better understanding of the solar wind–magnetosphere–ionosphere coupling process under northward IMF conditions. 

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2. Observations of three-dimensional ionospheric plasma properties in a space hurricane

   https://doi.org/10.3389/fspas.2024.1507824  

   Lu, Sheng; Xing, Zan-Yang; Zhang, Qing-He; Zhang, Yongliang; Oksavik, Kjellmar; Lyons, L R; Lockwood, Michael; Ma, Yu-Zhang; Wang, Xiang-Yu; Balan, N; et al (December 2024, Frontiers in Astronomy and Space Sciences)

   The space hurricane is a newly discovered large-scale three-dimensional magnetic vortex structure that spans the polar ionosphere and magnetosphere. It has been suggested to open a fast energy transport channel for the solar wind to invade Earth’s magnetosphere under northward interplanetary magnetic field (IMF) conditions. It is, therefore, an important phenomenon to understand the solar wind–magnetosphere–ionosphere coupling process under northward IMF conditions. In this study, we report the three-dimensional ionospheric plasma properties of a space hurricane event in the Northern Hemisphere observed by multiple instruments. Based on the convection velocity observations from ground-based radars and polar satellites, we confirm that the major modulation to the polar cap convection called a space hurricane rotates clockwise at the altitude of the ionosphere. Ground-based incoherent scatter radar and polar satellite observations reveal four features associated with the space hurricane: 1) strong plasma flow shears and being embedded in a clockwise lobe convection cell; 2) a major addition to the total energy deposition in the ionosphere–thermosphere system by Joule heating; 3) downward ionospheric electron transport; and 4) multiple ion-temperature enhancements in the sunward velocity region, likely from the spiral arms of the space hurricane. These results present, first, the impact of space hurricane on the low-altitude ionosphere and provide additional insights on the magnetospheric impact on structuring in the polar ionosphere. 

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3. How Do Space Hurricanes Disturb the Polar Thermosphere: A Statistical Survey

   https://doi.org/10.1029/2025GL115160  

   Xiu, Zhi‐Feng; Ma, Yu‐Zhang; Zhang, Qing‐He; Xing, Zan‐Yang; Lyons, Larry; Oksavik, Kjellmar; Zhang, Yong‐Liang; Hairston, Marc; Wang, Yong; Zhang, Duan; et al (April 2025, Geophysical Research Letters)

   Abstract The space hurricane is a polar cap auroral structure with strong flow shears and intense particle precipitation that can disturb the thermosphere under quiet geomagnetic conditions. Here the statistical characteristics of this interaction are surveyed using data from the Defense Meteorological Satellite Program and Gravity Field and Steady‐State Ocean Circulation Explorer satellites. The results confirm that space hurricanes modify the ion and neutral circulation in the polar cap through enhanced electric fields. Local precipitation, particularly >500 eV electrons, which raises the Pedersen conductance, leads to enhanced Joule heating and the generation of gravity waves. Electric fields play a leading role on the dawn side of the space hurricane. Gravity waves are also mainly located on the dawnside of the space hurricane, with a maximum vertical wind of 37 m/s and a 17% neutral density disturbance. These findings augment our awareness of magnetosphere‐polar ionosphere‐thermosphere coupling under quiet northward IMF conditions. 

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4. Direct Observation of the Space Hurricane Disturbed Polar Thermosphere

   https://doi.org/10.1029/2023GL106735  

   Xiu, Zhi‐Feng; Ma, Yu‐Zhang; Zhang, Qing‐He; Xing, Zan‐Yang; Zhang, Shun‐Rong; Zhang, Yong‐Liang; Oksavik, Kjellmar; Lyons, Larry; Lockwood, Michael; Wang, Yong (January 2024, Geophysical Research Letters)

   Abstract The space hurricane is a three‐dimensional magnetic vortex structure with strong flow shears and electron precipitation in the polar cap. This study investigates for the first time how a space hurricane disturbs the polar thermosphere. During the formation and development of the space hurricane, the directional reversal of the horizontal neutral wind and the plasma convection will both be relocated from the poleward auroral oval boundary to the edge of the space hurricane, but the neutral wind responds slower compared to the plasma convection. Strong flow shears in the space hurricane causes enhanced Joule heating in the polar cap, which heats the thermosphere and triggers Atmospheric Gravity Waves (AGWs). Statistical results reveal that significant AGWs mainly are located on the dawnside of the space hurricane, suggesting that the space hurricane plays a significant role in ion‐neutral coupling and generation of polar cap AGWs. 

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5. The Role of Diffuse Electron Precipitation in the Formation of Subauroral Polarization Streams

   https://doi.org/10.1029/2021JA029792  

   Lin, Dong; Sorathia, Kareem; Wang, Wenbin; Merkin, Viacheslav; Bao, Shanshan; Pham, Kevin; Wiltberger, Michael; Shi, Xueling; Toffoletto, Frank; Michael, Adam; et al (December 2021, Journal of Geophysical Research: Space Physics)

   Abstract The role of diffuse electron precipitation in the formation of subauroral polarization streams (SAPS) is investigated with the Multiscale Atmosphere‐Geospace Environment (MAGE) model. Diffuse precipitation is derived from the distribution of drifting electrons. SAPS manifest themselves as a separate mesoscale flow channel in the duskside ionosphere, which gradually merges with the primary auroral convection toward dayside as the equatorward auroral boundary approaches the poleward Region‐2 field‐aligned currents (FACs) boundary. SAPS expand to lower latitudes and toward the nightside during the main phase of a geomagnetic storm, associated with magnetotail earthward plasma flows building up the ring current and intensifying Region‐2 FACs and electron precipitation. SAPS shrink poleward and sunward as the interplanetary magnetic field turns northward. When diffuse precipitation is turned off in a controlled MAGE simulation, ring current and duskside Region‐2 FACs become weaker, but subauroral zonal ion drifts are still comparable to auroral convection. However, subauroral and auroral convection manifest as a single broad flow channel without showing any mesoscale structure. SAPS overlap with the downward Region‐2 FACs equatorward of diffuse precipitation, where poleward electric fields are strong due to a low conductance in the subauroral ionosphere. The Region‐2 FACs extend to latitudes lower than the diffuse precipitation because the ring current protons penetrate closer to the Earth than the electrons do. This study reproduces the key physics of SAPS formation and their evolution in the coupled magnetosphere‐ionosphere during a geomagnetic storm. Diffuse electron precipitation is demonstrated to play a critical role in determining SAPS location and structure. 

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