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3. Ionosphere over Ukrainian Antarctic Akademik Vernadsky station under minima of solar and magnetic activities, and daily insolation: case study for June 2019

Author

Marc R. Hairston, Dmytro Kotov, , Prague, Czech Republic, T. G. Zhivolup, A. I. Reznychenko, S. B. Kashcheyev, Oleksandr Bogomaz, A. V. Zalizovski, Vladimir Truhlik, Maryna Shulha, and Alexander Koloskov

Subjects
Electron density, ionosonde, satellite, lcsh:QC801-809, Defense Meteorological Satellite Program, Геокосмічні дослідження, Electron, lcsh:QC851-999, Atmospheric sciences, f2 layer peak height, Physics::Geophysics, electron and ion temperatures, reference model of ionosphere, lcsh:Geophysics. Cosmic physics, Physics::Space Physics, Environmental science, Solstice, Satellite, lcsh:Meteorology. Climatology, Ionosphere, electron density, Ionosonde, Southern Hemisphere, Physics::Atmospheric and Oceanic Physics
Abstract

We present ionospheric observational results obtained over Ukrainian Antarctic Akademik Vernadsky station. Ionospheric parameters (peak electron density and height, electron density and electron and ion temperatures in the topside) during the period near the local winter solstice in the Southern Hemisphere (June 28—29, 2019) are considered. The main objective is to show distinctive features of variations in ionospheric parameters during a prolonged period with very low solar and magnetic activities, and minimal daily insolation. Methods. F2 layer peak electron density and height were calculated from ionograms obtained with ionosonde installed at the station with subsequent profile inversion. Defense Meteorological Satellite Program (DMSP) and Swarm data acquired over the station are used as well. Diurnal variations of electron density, and electron and ion temperatures at the altitude of the satellites’ orbits were calculated using a set of sub-models of the International Reference Ionosphere-2016 (IRI-2016) model. Results. We found a very good agreement between the observed and model variations of F2 layer peak electron density. Significant (by ~2 times) nighttime enhancement of electron density was observed on June 29. Electron density models show the similar increase of the density at the same time interval but this enhancement is much more smoothed comparing with the observations. Peak height values obtained using ionosonde are very close to ones calculated with the IRI-2016 sub-models. Satellite data are in a good consistency with the IRI model predictions, especially for electron density obtained by Swarm satellite. Conclusions. Multi-instrumental observations revealed a number of unique features of the ionosphere over Antarctic Peninsula under minima of solar and magnetic activities, and daily insolation.

Published
2020

5. Auroral Heating of Plasma Patches Due to High‐Latitude Reconnection

Author

Joshua Semeter, Keisuke Hosokawa, Olga P. Verkhoglyadova, Kazuo Shiokawa, Michael Hirsch, Marc R. Hairston, Ashton S. Reimer, Matthew D. Zettergren, Yukitoshi Nishimura, Roger H. Varney, and Joaquin Diaz Pena

Subjects
Incoherent scatter, Sampling (statistics), Plasma, law.invention, Computer Science::Graphics, Geophysics, Space and Planetary Science, law, High latitude, Physics::Space Physics, Radar, Bay, Physics::Atmospheric and Oceanic Physics, Geology, Remote sensing
Abstract

This study exploits the volumetric sampling capabilities of the Resolute Bay Incoherent Scatter Radar (RISR-N) in collaboration with all-sky imagery and in-situ measurements (DMSP) to examine the i...

Published
2021
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6. Dual-lobe reconnection and cusp-aligned auroral arcs

Author

Brian J. Anderson, Larry J. Paxton, J. A. Carter, Gemma Bower, Marc R. Hairston, and Stephen E. Milan

Subjects
Geomagnetic storm, medicine.anatomical_structure, Physics::Space Physics, medicine, Cusp (anatomy), Astrophysics, Interplanetary magnetic field, Geology, Lobe, Physics::Geophysics
Abstract

Following the St. Patrick's Day (17 March) geomagnetic storm of 2013, the interplanetary magnetic field had near-zero clock angle for almost two days. Throughout this period multiple cusp-aligned a...

Published
2021
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8. Hemispheric Asymmetries in Poynting Flux Derived From DMSP Spacecraft

Author

Delores J. Knipp, W. Robin Coley, L. M. Kilcommons, and Marc R. Hairston

Subjects
Physics, Geophysics, Spacecraft, business.industry, Poynting vector, General Earth and Planetary Sciences, Flux, Defense Meteorological Satellite Program, business, Atmospheric sciences
Abstract

We provide high-resolution maps of quasi-static Poynting flux (PF) in each hemisphere based on nine-satellite years of Defense Meteorological Satellite Program (DMSP) data. Conjugate comparisons fr...

Published
2021
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11. ASHLEY: A New Empirical Model for the High‐Latitude Electron Precipitation and Electric Field

Author

Yue Deng, Astrid Maute, L. M. Kilcommons, Qingyu Zhu, Delores J. Knipp, and Marc R. Hairston

Subjects
Physics, Atmospheric Science, 010504 meteorology & atmospheric sciences, Electron precipitation, 01 natural sciences, Physics::Geophysics, Computational physics, Electric field, High latitude, Physics::Space Physics, 0103 physical sciences, Energy spectrum, Astrophysics::Solar and Stellar Astrophysics, Electric potential, Joule heating, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, 0105 earth and related environmental sciences
Abstract

In this study, a new high-latitude empirical model is introduced, named for Auroral energy Spectrum and High-Latitude Electric field variabilitY (ASHLEY). This model aims to improve specifications ...

Published
2021
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12. Electrodynamics surrounding polar cap auroral arcs

Author

Kjellmar Oksavik, Marc R. Hairston, Jone Peter Reistad, and Amalie Ø. Hovland

Subjects
Physics, Physics::Space Physics, Astrophysics, Polar cap, Physics::Atmospheric and Oceanic Physics
Abstract

This multi-instrument case study investigates the electrodynamics surrounding polar cap auroral arcs. A long-lasting auroral arc is observed in the high latitude dusk-sector at ~80° Apex latitude in the northern hemisphere. Ion drift measurements from the SSIES system on the DMSP spacecraft have been combined with multiple ground-based observations. Line of sight velocity data from three polar latitude high-frequency Super Dual Auroral Radar Network (SuperDARN) radars show mesoscale structure in the ionospheric convection in the region surrounding the arc. The convection electric field in this region is modelled using a Spherical Elementary Convection Systems (SECS) technique, using curl-free basis functions only. The result is a regional model of the ionospheric convection based on the fairly dense and distributed flow observations and the curl-free constraint. The model is compared to optical data of the auroral arc from two high latitude Redline Emission Geospace Observatory (REGO) all-sky imagers as well as UV images and particle measurements from the DMSP spacecraft to describe the local electrodynamics in the vicinity of the high latitude arc throughout the event.

Published
2021
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13. Dual-lobe reconnection and horse-collar auroras

Author

Benoît Hubert, J. A. Carter, Larry J. Paxton, Suzanne M. Imber, Marc R. Hairston, Brian J. Anderson, Stephen E. Milan, and Gemma Bower

Subjects
Physics, medicine.anatomical_structure, medicine, Astrophysics, DUAL (cognitive architecture), Interplanetary magnetic field, Mechanism (sociology), Lobe, Collar
Abstract

We propose a mechanism for the formation of the horse-collar auroral configuration common during periods of strongly northwards interplanetary magnetic field, invoking the action of dual-lobe reconnection (DLR). Auroral observations are provided by the Imager for Magnetopause-to-Auroras Global Exploration (IMAGE) satellite and spacecraft of the Defense Meteorological Satellite Program (DMSP). We also use ionospheric flow measurements from DMSP and polar maps of field-aligned currents (FACs) derived from the Active Magnetosphere and Planetary Electrodynamics Response Experiment (AMPERE). Sunward convection is observed within the dark polar cap, with antisunwards flows within the horse-collar auroral region, together with the NBZ FAC distribution expected to be associated with DLR. We suggest that newly-closed flux is transported antisunwards and to dawn and dusk within the reverse lobe cell convection pattern associated with DLR, causing the polar cap to acquire a teardrop shape and weak auroras to form at high latitudes. Horse-collar auroras are a common feature of the quiet magnetosphere, and this model provides a first understanding of their formation, resolving several outstanding questions regarding the nature of DLR and the magnetospheric structure and dynamics during northwards IMF. The model can also provide insights into the trapping of solar wind plasma by the magnetosphere and the formation of a low-latitude boundary layer and cold, dense plasma sheet. We speculate that prolonged DLR could lead to a fully closed magnetosphere, with the formation of horse-collar auroras being an intermediate step.

Published
2021
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14. Observations and Modeling of the Ionospheric Topside Response to the Moon’s Shadow During Solar Eclipses

Author

Sebastijan Mrak, W. R. Coley, Joshua Semeter, and Marc R. Hairston

Subjects
Spacecraft, business.industry, Shadow, Astronomy, Ionosphere, business, Geology
Abstract

In previous work (Hairston et al., GRL doi 10.1029/2018GL077381, 2018) we showed the topside F-layer (~850 km) electron temperatures measured by two DMSP spacecraft as they flew through the Moon’s ...

Published
2020
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15. Dual‐Lobe Reconnection and Horse‐Collar Auroras

Author

Suzanne M. Imber, Marc R. Hairston, Gemma Bower, Brian J. Anderson, Benoît Hubert, Larry J. Paxton, J. A. Carter, and Stephen E. Milan

Subjects
Physics, 010504 meteorology & atmospheric sciences, Astrophysics, DUAL (cognitive architecture), 01 natural sciences, Lobe, Collar, Geophysics, medicine.anatomical_structure, Physics::Plasma Physics, Space and Planetary Science, Physics::Space Physics, medicine, Astrophysics::Solar and Stellar Astrophysics, Interplanetary magnetic field, Mechanism (sociology), 0105 earth and related environmental sciences
Abstract

We propose a mechanism for the formation of the horse-collar auroral configuration during periods of strongly northward interplanetary magnetic field (IMF), invoking the action of dual-lobe reconnection (DLR). Auroral observations are provided by the Imager for Magnetopause-to-Aurora Global Exploration (IMAGE) satellite and spacecraft of the Defense Meteorological Satellite Program (DMSP). We also use ionospheric flow measurements from DMSP and polar maps of field-aligned currents (FACs) derived from the Active Magnetosphere and Planetary Electrodynamics Response Experiment (AMPERE). Sunward convection is observed within the dark polar cap, with antisunward flows within the horse-collar auroral region, together with the NBZ FAC distribution expected to be associated with DLR. We suggest that newly closed flux is transported antisunward and to dawn and dusk within the reverse lobe cell convection pattern associated with DLR, causing the polar cap to acquire a teardrop shape and weak auroras to form at high latitudes. Horse-collar auroras are a common feature of the quiet magnetosphere, and this model provides a first understanding of their formation, resolving several outstanding questions regarding the nature of DLR and the magnetospheric structure and dynamics during northward IMF. The model can also provide insights into the trapping of solar wind plasma by the magnetosphere and the formation of a low-latitude boundary layer and cold, dense plasma sheet. We speculate that prolonged DLR could lead to a fully closed magnetosphere, with the formation of horse-collar auroras being an intermediate step. publishedVersion

Published
2020
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17. Dawnside Auroral Polarization Streams

Author

Marc R. Hairston, Yongliang Zhang, Larry R. Lyons, Jiang Liu, Chih‐Ping Wang, and Ying Zou

Subjects
Physics, Geophysics, Space and Planetary Science, STREAMS, Conductivity, Polarization (waves), Computational physics
Published
2020
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18. On the Production of Ionospheric Irregularities Via Kelvin-Helmholtz Instability Associated with Cusp Flow Channels

Author

K. Deshpande, Lasse Boy Novock Clausen, Kjellmar Oksavik, Yaqi Jin, M. D. Zettergren, Joran Moen, Andres Spicher, Marc R. Hairston, and Lisa Baddeley

Subjects
Cusp (singularity), Physics, 010504 meteorology & atmospheric sciences, Mechanics, Space weather, 01 natural sciences, 010305 fluids & plasmas, Helmholtz instability, Geophysics, Flow (mathematics), 13. Climate action, Space and Planetary Science, 0103 physical sciences, Physics::Space Physics, Ionosphere, 0105 earth and related environmental sciences
Abstract

We present a multi‐instrument multiscale study of a channel of enhanced, inhomogeneous flow in the cusp ionosphere occurring on November 30, 2014. We provide evidence that strong Global Navigation Satellite System (GNSS) phase scintillations indices (σϕ>0.5 rad) can arise from such events, indicating that they are important in the context of space weather impacts on technology. We compare in detail two‐dimensional maps of ionospheric density, velocity, and temperatures obtained by the European Incoherent Scatter Scientific Association Svalbard Radar with scintillation indices detected from a network of four GNSS receivers around Svalbard and examine the different sources of free energy for irregularity creation. We observe that the strongest phase scintillations occur on the poleward side of the flow channel in a region of sheared plasma motion and structured low‐energy particle precipitation. As inhomogeneous plasma flows are evident in our observations, we perform a quantitative, nonlinear analysis of the Kelvin–Helmholtz instability (KHI) and its impact on phase scintillations using numerical simulations from the first principles‐based Geospace Environment Model of Ion‐Neutral Interactions and Satellite‐beacon Ionospheric‐scintillation Global Model of the upper Atmosphere. Using representative values consistent with the radar data, we show that KHI can efficiently create density structures along with considerable scintillations and is thus likely to contribute significantly under similar conditions, which are frequent in the cusp. publishedVersion

Published
2020

19. Impacts of Binning Methods on High‐Latitude Electrodynamic Forcing: Static Versus Boundary‐Oriented Binning Methods

Author

Yue Deng, Qingyu Zhu, L. M. Kilcommons, Marc R. Hairston, Yun‐Ju Chen, Robert J. Redmon, E. J. Mitchell, Astrid Maute, Arthur D. Richmond, and Delores J. Knipp

Subjects
010504 meteorology & atmospheric sciences, Boundary (topology), Geophysics, Forcing (mathematics), 01 natural sciences, 010305 fluids & plasmas, Space and Planetary Science, Electric field, High latitude, 0103 physical sciences, Joule heating, Geology, 0105 earth and related environmental sciences
Published
2020
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20. Statistical Study of the Relationship Between Ion Upflow and Field-Aligned Current in the Topside Ionosphere for Both Hemispheres During Geomagnetic Disturbed and Quiet Time

Author

Marc R. Hairston, Zan-Yang Xing, Larry R. Lyons, Shan-Yu Zhou, P. T. Jayachandran, Qing-He Zhang, Yu-Zhang Ma, Yong Wang, and Kjellmar Oksavik

Subjects
Physics, Geophysics, Earth's magnetic field, Field (physics), Space and Planetary Science, QUIET, Topside ionosphere, Current (fluid), Ion
Abstract

A statistical study of ion upflow and field‐aligned currents (FACs) has been performed in the topside ionosphere of both hemispheres for magnetic quiet and disturbed times by using DMSP satellite observations from 2010–2013. Distributions in MLT/MLat reveal that ion upflow occurrence shows a dawn‐dusk asymmetry distribution that matches well with the Region 1 FACs. In addition, there are highest occurrence regions near noon and within the midnight auroral disturbance area, corresponding to dayside cusp and nightside auroral disturbance regions, respectively. Both the ion upflow occurrence and FAC regions expand equatorward to a wider area during disturbed times. publishedVersion

Published
2020

21. Topside Ionospheric Electron Temperature Observations of the 21 August 2017 Eclipse by DMSP Spacecraft

Author

W. R. Coley, M. D. Perdue, Robert Power, Ben Holt, Marc R. Hairston, Sebastijan Mrak, Angeline G. Burrell, and Matthew Depew

Subjects
010504 meteorology & atmospheric sciences, Spacecraft, business.industry, Astronomy, 01 natural sciences, Geophysics, 0103 physical sciences, Topside ionosphere, General Earth and Planetary Sciences, Environmental science, Electron temperature, Ionosphere, business, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Eclipse
Published
2018
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22. DMSP observations of high latitude Poynting flux during magnetic storms

Author

Marc R. Hairston, Yanshi Huang, Cheryl Y. Huang, Yi-Jiun Su, and Thomas Sotirelis

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, Defense Meteorological Satellite Program, Storm, Atmospheric sciences, 01 natural sciences, Physics::Geophysics, Latitude, Geophysics, Flux (metallurgy), Space and Planetary Science, High latitude, Physics::Space Physics, 0103 physical sciences, Poynting vector, Environmental science, Polar, Astrophysics::Earth and Planetary Astrophysics, 010303 astronomy & astrophysics, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences
Abstract

Previous studies have demonstrated that energy can enter the high-latitude regions of the Ionosphere-Thermosphere (IT) system on open field lines. To assess the extent of high-latitude energy input, we have carried out a study of Poynting flux measured by the Defense Meteorological Satellite Program (DMSP) satellites during magnetic storms. We report sporadic intense Poynting fluxes measured by four DMSP satellites at polar latitudes during two moderate magnetic storms which occurred in August and September 2011. Comparisons with a widely used empirical model for energy input to the IT system show that the model does not adequately capture electromagnetic (EM) energy at very high latitudes during storms. We have extended this study to include more than 30 storm events and find that intense EM energy is frequently detected poleward of 75° magnetic latitude.

Published
2017
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23. Storm time coupling between the magnetosheath and the polar ionosphere

Author

L. M. Kilcommons, Marc R. Hairston, and William J. Burke

Subjects
Physics, Coupling (physics), Geophysics, Magnetosheath, 010504 meteorology & atmospheric sciences, Space and Planetary Science, Polar, Storm, Ionosphere, 010502 geochemistry & geophysics, 01 natural sciences, 0105 earth and related environmental sciences
Published
2017
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24. Testing nowcasts of the ionospheric convection from the expanding and contracting polar cap model

Author

Stephen E. Milan, M.-T. Walach, Tim K. Yeoman, Benoît Hubert, and Marc R. Hairston

Subjects
Convection, Atmospheric Science, 010504 meteorology & atmospheric sciences, Defense Meteorological Satellite Program, Super Dual Auroral Radar Network, Magnetic reconnection, Context (language use), Geophysics, 01 natural sciences, 13. Climate action, Physics::Space Physics, 0103 physical sciences, Substorm, Astrophysics::Solar and Stellar Astrophysics, Magnetopause, Ionosphere, 010303 astronomy & astrophysics, Physics::Atmospheric and Oceanic Physics, Geology, 0105 earth and related environmental sciences
Abstract

The expanding/contracting polar cap (ECPC) model, or the time-dependent Dungey cycle, provides a theoretical framework for understanding solar wind-magnetosphere-ionosphere coupling. The ECPC describes the relationship between magnetopause reconnection and substorm growth phase, magnetotail reconnection and substorm expansion phase, associated changes in auroral morphology, and ionospheric convective motions. Despite the many successes of the model, there has yet to be a rigorous test of the predictions or nowcasts made regarding ionospheric convection, which remains a final hurdle for the validation of the ECPC. In this study we undertake a comparison of ionospheric convection, as measured in situ by ion drift meters on board DMSP (Defense Meteorological Satellite Program) satellites and from the ground by SuperDARN (Super Dual Auroral Radar Network), with motions nowcasted by a theoretical model. The model is coupled to measurements of changes in the size of the polar cap made using global auroral imagery from the IMAGE FUV (Imager for Magnetopause to Aurora Global Exploration Far Ultraviolet) instrument, as well as the dayside reconnection rate, estimated using the OMNI data set. The results show that we can largely nowcast the magnitudes of ionospheric convection flows using the context of our understanding of magnetic reconnection at the magnetopause and in the magnetotail.

Published
2017
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25. RISR‐N observations of the IMF B y influence on reverse convection during extreme northward IMF

Author

J. M. Ruohoniemi, Marc R. Hairston, J. B. H. Baker, Michael J. Nicolls, M. Maimaiti, and C. R. Clauer

Subjects
Convection, Physics, 010504 meteorology & atmospheric sciences, Flow (psychology), Incoherent scatter, Magnitude (mathematics), Magnetic reconnection, Geophysics, Noon, 01 natural sciences, 010305 fluids & plasmas, Space and Planetary Science, Physics::Space Physics, 0103 physical sciences, Magnetopause, Interplanetary magnetic field, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences
Abstract

Previous studies have demonstrated that the high-latitude ionospheric convection is strongly influenced by the interplanetary magnetic field (IMF) direction. However, the temporal details of how the convection transitions from one state to another is still not understood completely. In this study, we analyze an interval on September 12, 2014 which provided a rare opportunity to examine dynamic variations in the dayside convection throat as the IMF transitioned from strong By+ to strong Bz+. Between 18:00 - 20:00 UT the northward face of the Resolute Bay Incoherent Scatter Radar (RISR-N) rotated through the noon sector and directly measured strengthening reverse convection flows in the dayside throat region that peaked at ∼2800m/s. Near-simultaneous measurements from DMSP satellites confirm the magnitude of the reverse convection and its proximity to the cusp. Time-series comparison of the RISR-N north-south flows with the IMF Bz component shows a remarkably high correlation, suggestive of strong linear coupling, with no sign of velocity saturation. Likewise, the east-west flow variations were highly correlated with the changes in IMF By. However, time-lagged correlation analysis reveals that the IMF By influence acted on a time-scale 10 minutes shorter than that of the Bz component. As a consequence, the manner in which the convection transitioned from the strong By+ condition to the strong Bz+ condition is inconsistent with either the anti-parallel and component reconnection models. Instead, we suggest that these particular observations are consistent with two separate reconnection sites on the magnetopause driven independently by the IMF By and Bz components.

Published
2017
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26. Equatorial ionospheric plasma drifts and O + concentration enhancements associated with disturbance dynamo during the 2015 St. Patrick's Day magnetic storm

Author

Gordon R. Wilson, Chao Song Huang, Yongliang Zhang, Wenbin Wang, Marc R. Hairston, and Jing Liu

Subjects
Geomagnetic storm, Disturbance (geology), 010504 meteorology & atmospheric sciences, Plasma, Geophysics, Atmospheric sciences, 01 natural sciences, Space and Planetary Science, 0103 physical sciences, Ionosphere, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences, Dynamo
Published
2016
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27. Multispacecraft observations and modeling of the 22/23 June 2015 geomagnetic storm

Author

Daniel T. Welling, Patricia H. Reiff, Antoun G. Daou, Kevin Genestreti, Michael O. Chandler, S. A. Fuselier, Stanislav Sazykin, Christopher T. Russell, Marc R. Hairston, Victoria N. Coffey, Brian J. Anderson, and Rumi Nakamura

Subjects
Geomagnetic storm, Physics, 010504 meteorology & atmospheric sciences, Magnetosphere, Defense Meteorological Satellite Program, Geophysics, Space weather, Atmospheric sciences, 01 natural sciences, Solar cycle, Physics::Space Physics, 0103 physical sciences, General Earth and Planetary Sciences, Van Allen Probes, Ionosphere, Magnetospheric Multiscale Mission, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences
Abstract

The magnetic storm of 22-23 June 2015 was one of the largest in the current solar cycle. We present in situ observations from the Magnetospheric Multiscale Mission (MMS) and the Van Allen Probes (VAP) in the magnetotail, field-aligned currents from AMPERE (Active Magnetosphere and Planetary Electrodynamics Response), and ionospheric flow data from Defense Meteorological Satellite Program (DMSP). Our real-time space weather alert system sent out a "red alert," correctly predicting Kp indices greater than 8. We show strong outflow of ionospheric oxygen, dipolarizations in the MMS magnetometer data, and dropouts in the particle fluxes seen by the MMS Fast Plasma Instrument suite. At ionospheric altitudes, the AMPERE data show highly variable currents exceeding 20 MA. We present numerical simulations with the Block Adaptive Tree-Solarwind - Roe - Upwind Scheme (BATS-R-US) global magnetohydrodynamic model linked with the Rice Convection Model. The model predicted the magnitude of the dipolarizations, and varying polar cap convection patterns, which were confirmed by DMSP measurements.

Published
2016
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28. Observation of a unipolar field-aligned current system associated with IMF By -triggered theta auroras

Author

Marc R. Hairston and Masakazu Watanabe

Subjects
Physics, 010504 meteorology & atmospheric sciences, Field (physics), Polarity (physics), Northern Hemisphere, Geophysics, 01 natural sciences, Space and Planetary Science, Satellite data, 0103 physical sciences, Ionosphere, Current (fluid), Interplanetary magnetic field, 010303 astronomy & astrophysics, Past study, 0105 earth and related environmental sciences
Abstract

We investigate the existence of a specific field-aligned current (FAC) system predicted by numerical magnetohydrodynamic simulations in a past study. The FAC system is expected to occur when a drifting θ aurora is formed in response to a stepwise transition of interplanetary magnetic field (IMF) By during strongly northward IMF periods. When the IMF By changes from positive to negative, a crossbar forms in the Northern Hemisphere that moves dawnward, while in the Southern Hemisphere the crossbar moves in the opposite direction. The crossbar motion reverses when the IMF By changes from negative to positive. The FAC system appears on the trailing side of the drifting crossbar of the θ aurora as it moves either dawnward or duskward. When the θ aurora is drifting dawnward, the FACs flow into the ionosphere. The FAC polarity reverses when the θ aurora is drifting duskward. Using low-altitude satellite data, we confirmed the real existence of the above model-predicted FAC system.

Published
2016
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29. The auroral ionosphere TEC response to an interplanetary shock

Author

Joran Moen, Yaqi Jin, Marc R. Hairston, and Xiaoyan Zhou

Subjects
010504 meteorology & atmospheric sciences, TEC, Storm, Geophysics, Space weather, 01 natural sciences, Shock (mechanics), 0103 physical sciences, General Earth and Planetary Sciences, Environmental science, Ionosphere, Interplanetary spaceflight, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences
Published
2016
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30. Formation of polar ionospheric tongue of ionization during minor geomagnetic disturbed conditions

Author

N. Balan, Jing Liu, Evan G. Thomas, Wenbin Wang, Takuji Nakamura, Libo Liu, Marc R. Hairston, and Takanori Nishiyama

Subjects
Geomagnetic storm, Daytime, Total electron content, TEC, Equatorial electrojet, Geophysics, Atmospheric sciences, Physics::Geophysics, Earth's magnetic field, Space and Planetary Science, Middle latitudes, Physics::Space Physics, Ionosphere, Physics::Atmospheric and Oceanic Physics, Geology
Abstract

Previous investigations of ionospheric storm-enhanced density (SED) and tongue of ionization (TOI) focused mostly on the behavior of TOI during intense geomagnetic storms. Little attention has been paid to the spatial and temporal variations of TOI during weak to moderate geomagnetic disturbed conditions. In this paper we investigate the source and development of TOI during a moderate geomagnetic storm on 14 October 2012. Multi-instrumental observations including GPS total electron content (TEC), Defense Meteorological Satellite Program (DMSP) in situ measured total ion concentration and ion drift velocity, SuperDARN measured polar ion convection patterns, and electron density profiles from the Poker Flat Incoherent Scatter Radar (PFISR) have been utilized in the current analysis. GPS TEC maps show salient TOI structures persisting for about 5 h over high latitudes of North America on 14 October 2012 in the later recovery phase of the storm when the magnitudes of IMF By and Bz were less than 5 nT. The PFISR electron density profiles indicate that the extra ionization for TEC enhancements mainly occurred in the topside ionosphere with no obvious changes in the bottomside ionosphere and vertical plasma drifts. Additionally, there were no signatures of penetration electric fields in the equatorial electrojet data and upward ion drifts at high latitudes. At the same time, strong subauroral polarization streams with ion drift speeds exceeding 2.5 km/s carried sunward fluxes and migrated toward lower latitudes for about 5° based on the DMSP cross-track drift measurements. Based on those measurements, we postulate that the combined effects of initial build-up of ionization at midlatitudes through daytime production of ionization and equatorward (or less poleward than normal daytime) neutral wind reducing downward diffusion along the inclined filed lines, and an expanded polar ion convection pattern and its associated horizontal plasma transport are important in the formation of the TOI.

Published
2015
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31. Study of the Equatorial and Low-Latitude Electrodynamic and Ionospheric Disturbances During the 22-23 June 2015 Geomagnetic Storm Using Ground-Based and Spaceborne Techniques

Author

W. R. Coley, Elvira Astafyeva, Patrick Alken, Pierdavide Coïsson, Marc R. Hairston, Kornyanat Hozumi, and Irina Zakharenkova

Subjects
Geomagnetic storm, Ionospheric storm, 010504 meteorology & atmospheric sciences, Total electron content, Equatorial electrojet, Storm, Geophysics, 01 natural sciences, Solar cycle, Space and Planetary Science, 0103 physical sciences, Ionosphere, Interplanetary magnetic field, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences
Abstract

We use a set of ground-based instruments (Global Positioning System receivers, ionosondes, magnetometers) along with data of multiple satellite missions (Swarm, C/NOFS, DMSP, GUVI) to analyze the equatorial and low-latitude electrodynamic and ionospheric disturbances caused by the geomagnetic storm of 22-23 June 2015, which is the second largest storm in the current solar cycle. Our results show that at the beginning of the storm, the equatorial electrojet (EEJ) and the equatorial zonal electric fields were largely impacted by the prompt penetration electric fields (PPEF). The PPEF were first directed eastward and caused significant ionospheric uplift and positive ionospheric storm on the dayside, and downward drift on the nightside. Furthermore, about 45 min after the storm commencement, the interplanetary magnetic field (IMF) Bz component turned northward, leading to the EEJ changing sign to westward, and to overall decrease of the vertical total electron content (VTEC) and electron density on the dayside. At the end of the main phase of the storm, and with the second long-term IMF Bz southward turn, we observed several oscillations of the EEJ, which led us to conclude that at this stage of the storm, the disturbance dynamo effect was already in effect, competing with the PPEF and reducing it. Our analysis showed no significant upward or downward plasma motion during this period of time; however, the electron density and the VTEC drastically increased on the dayside (over the Asian region). We show that this second positive storm was largely influenced by the disturbed thermospheric conditions.

Published
2017

32. Conjugate Aurora Location During a Strong IMF By Storm

Author

Patricia H. Reiff, Marc R. Hairston, William Longley, and Antoun G. Daou

Subjects
Physics, 010504 meteorology & atmospheric sciences, 0103 physical sciences, Storm, Geophysics, Interplanetary magnetic field, 010303 astronomy & astrophysics, 01 natural sciences, 0105 earth and related environmental sciences, Conjugate
Published
2017
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33. Solar filament impact on 21 January 2005: Geospace consequences

Author

David S. Evans, Cynthia A Cattell, D. L. De Zeeuw, Harald U. Frey, Olga P. Verkhoglyadova, Xiaohua Fang, Marit Irene Sandanger, Stephen B. Mende, B. T. Tsurutani, Walter D. Gonzalez, Roderick A. Heelis, Marc R. Hairston, Michael W. Liemohn, Thomas Sotirelis, M. W. Thomsen, Finn Søraas, Ward B. Manchester, Janet U. Kozyra, Larry J. Paxton, C. P. Escoubet, Lutz Rastaetter, Aaron J. Ridley, M.-C. Fok, and Gang Lu

Subjects
Geomagnetic storm, Physics, Plasma sheet, Solar cycle 23, Geophysics, Astrophysics, Space weather, Solar prominence, Space and Planetary Science, Physics::Space Physics, Coronal mass ejection, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, Interplanetary magnetic field, Ring current
Abstract

On 21 January 2005, a moderate magnetic storm produced a number of anomalous features, some seen more typically during superstorms. The aim of this study is to establish the differences in the space environment from what we expect (and normally observe) for a storm of this intensity, which make it behave in some ways like a superstorm. The storm was driven by one of the fastest interplanetary coronal mass ejections in solar cycle 23, containing a piece of the dense erupting solar filament material. The momentum of the massive solar filament caused it to push its way through the flux rope as the interplanetary coronal mass ejection decelerated moving toward 1 AU creating the appearance of an eroded flux rope (see companion paper by Manchester et al. (2014)) and, in this case, limiting the intensity of the resulting geomagnetic storm. On impact, the solar filament further disrupted the partial ring current shielding in existence at the time, creating a brief superfountain in the equatorial ionosphere—an unusual occurrence for a moderate storm. Within 1 h after impact, a cold dense plasma sheet (CDPS) formed out of the filament material. As the interplanetary magnetic field (IMF) rotated from obliquely to more purely northward, the magnetotail transformed from an open to a closed configuration and the CDPS evolved from warmer to cooler temperatures. Plasma sheet densities reached tens per cubic centimeter along the flanks—high enough to inflate the magnetotail in the simulation under northward IMF conditions despite the cool temperatures. Observational evidence for this stretching was provided by a corresponding expansion and intensification of both the auroral oval and ring current precipitation zones linked to magnetotail stretching by field line curvature scattering. Strong Joule heating in the cusps, a by-product of the CDPS formation process, contributed to an equatorward neutral wind surge that reached low latitudes within 1–2 h and intensified the equatorial ionization anomaly. Understanding the geospace consequences of extremes in density and pressure is important because some of the largest and most damaging space weather events ever observed contained similar intervals of dense solar material.

Published
2014
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34. Storm-time meridional flows: a comparison of CINDI observations and model results

Author

Russell Stoneback, Naomi Maruyama, Marc R. Hairston, and W. R. Coley

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, Equator, Zonal and meridional, Atmospheric sciences, 01 natural sciences, Physics::Geophysics, Electric field, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Astrophysics::Solar and Stellar Astrophysics, lcsh:Science, 010303 astronomy & astrophysics, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Geomagnetic storm, lcsh:QC801-809, Geology, Astronomy and Astrophysics, Storm, Geophysics, lcsh:QC1-999, lcsh:Geophysics. Cosmic physics, 13. Climate action, Space and Planetary Science, Physics::Space Physics, Polar, lcsh:Q, Astrophysics::Earth and Planetary Astrophysics, Ionosphere, lcsh:Physics, Dynamo
Abstract

During a large geomagnetic storm, the electric field from the polar ionosphere can expand far enough to affect the mid-latitude and equatorial electric fields. These changes in the equatorial zonal electric field, called the penetration field, will cause changes in the meridional ion flows that can be observed by radars and spacecraft. In general this E × B ion flow near the equator caused by the penetration field during undershielding conditions will be upward on the dayside and downward on the nightside of the Earth. Previous analysis of the equatorial meridional flows observed by CINDI instrument on the C/NOFS spacecraft during the 26 September 2011 storm showed that all of the response flows on the dayside were excess downward flows instead of the expected upward flows. These observed storm-time responses are compared to a prediction from a physics-based coupled model of thermosphere–ionosphere–inner-magnetosphere in an effort to explain these observations. The model results suggest that the equatorial downward flow could be attributed to a combined effect of the overshielding and disturbance dynamo processes. However, some discrepancy between the model and observation indicates a need for improving our understanding of how sensitive the equatorial electric field is to various model input parameters that describe the magnetosphere–ionosphere coupling processes.

Published
2014

35. Topside equatorial zonal ion velocities measured by C/NOFS during rising solar activity

Author

Marc R. Hairston, Rodney A. Heelis, Russell Stoneback, and W. R. Coley

Subjects
Solar minimum, Atmospheric Science, lcsh:QC801-809, Geology, Astronomy and Astrophysics, Atmospheric sciences, F region, lcsh:QC1-999, Latitude, Physics::Geophysics, lcsh:Geophysics. Cosmic physics, Earth's magnetic field, Altitude, Space and Planetary Science, Local time, Physics::Space Physics, Earth and Planetary Sciences (miscellaneous), lcsh:Q, Astrophysics::Earth and Planetary Astrophysics, Ionosphere, Longitude, lcsh:Science, Physics::Atmospheric and Oceanic Physics, lcsh:Physics
Abstract

The Ion Velocity Meter (IVM), a part of the Coupled Ion Neutral Dynamic Investigation (CINDI) instrument package on the Communication/Navigation Outage Forecast System (C/NOFS) spacecraft, has made over 5 yr of in situ measurements of plasma temperatures, composition, densities, and velocities in the 400–850 km altitude range of the equatorial ionosphere. These measured ion velocities are then transformed into a coordinate system with components parallel and perpendicular to the geomagnetic field allowing us to examine the zonal (horizontal and perpendicular to the geomagnetic field) component of plasma motion over the 2009–2012 interval. The general pattern of local time variation of the equatorial zonal ion velocity is well established as westward during the day and eastward during the night, with the larger nighttime velocities leading to a net ionospheric superrotation. Since the C/NOFS launch in April 2008, F10.7 cm radio fluxes have gradually increased from around 70 sfu to levels in the 130–150 sfu range. The comprehensive coverage of C/NOFS over the low-latitude ionosphere allows us to examine variations of the topside zonal ion velocity over a wide level of solar activity as well as the dependence of the zonal velocity on apex altitude (magnetic latitude), longitude, and solar local time. It was found that the zonal ion drifts show longitude dependence with the largest net eastward values in the American sector. The pre-midnight zonal drifts show definite solar activity (F10.7) dependence. The daytime drifts have a lower dependence on F10.7. The apex altitude (magnetic latitude) variations indicate a more westerly flow at higher altitudes. There is often a net topside subrotation at low F10.7 levels, perhaps indicative of a suppressed F region dynamo due to low field line-integrated conductivity and a low F region altitude at solar minimum.

Published
2014

36. F region dusk ion temperature spikes at the equatorward edge of the high‐latitude convection pattern

Author

Michael J. Nicolls, P. G. Richards, L. V. Goodwin, J.-P. St.-Maurice, and Marc R. Hairston

Subjects
Convection, Physics, Geophysics, Earth's magnetic field, Physics::Space Physics, Incoherent scatter, General Earth and Planetary Sciences, Polar, Dusk, Plasmasphere, F region, Ion
Abstract

Using Poker Flat Incoherent Scatter Radar data from the International Polar Year, we observed unexpected short-lived enhancements of a few 100 K in the F region ion temperature, or “Ti spikes”, in conjunction with sharp F region plasma density drops near the dusk plasmapause. The geomagnetic conditions were moderately to weakly disturbed and the dusk spikes were often the largest Ti values recorded within the day. Taking various other observations into consideration, we conclude that the radar observed ion frictional heating events driven by large ion-neutral relative drifts caused by temporary intensifications in the convection pattern. The heating rate was enhanced through an increase in the size of the convection pattern, causing the neutrals just poleward of the dusk plasmapause to be moving antisunward while ions were moving sunward.

Published
2014
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37. Radio-tomographic images of postmidnight equatorial plasma depletions

Author

Carl L. Siefring, Matthew R. Wilkens, Cesar E. Valladares, Jorge L. Chau, Jonathan Krall, Marc R. Hairston, Joseph Huba, W. Robin Coley, Roderick A. Heelis, Matthew A. Hei, Paul A. Bernhardt, and César De la Jara

Subjects
Physics, Electron density, Geophysics, Total electron content, Ultra high frequency, Electric field, TEC, General Earth and Planetary Sciences, Satellite, Plasma, Astrophysics, Ionosphere
Abstract

[1] For the first time, equatorial plasma depletions (EPDs) have been imaged in the longitude-altitude plane using radiotomography. High-resolution (~10 km) reconstructions of electron density were derived from total electron content (TEC) measurements provided by a receiver array in Peru. TEC data were obtained from VHF/UHF signals transmitted by the Coherent Electromagnetic Radio Tomography (CERTO) beacon on the C/NOFS satellite. EPDs generated premidnight were observed near dawn. On one night, the bubble densities were highly reduced, 100–1000 km wide, and embedded within a layerlike ionosphere. Three nights later, the EPDs exhibited similar features but were embedded in a locally uplifted ionosphere. The C/NOFS in situ instruments detected a dawn depletion where the reconstruction showed lifted EPDs, implying that the postmidnight electric fields raised sections of ionosphere to altitudes where embedded/reactivated fossil EPDs were detected as dawn depletions. Satellites flying under domelike distortions of the ionosphere may observe these distortions as broad plasma decreases (BPDs).

Published
2014
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39. Imaging magnetospheric boundaries at ionospheric heights

Author

Michael Mendillo, Jeffrey Baumgardner, Marc R. Hairston, Cesare Barbieri, Kevin Druis Merenda, Steven M. Smith, Theodore A. Fritz, Rod Heelis, J. Wroten, and Carlos Martinis

Subjects
Geomagnetic storm, Defense Meteorological Satellite Program, Magnetosphere, Plasmasphere, Geophysics, symbols.namesake, Space and Planetary Science, Van Allen radiation belt, Physics::Space Physics, symbols, Ionosphere, Geology, Zenith, Ring current
Abstract

[1] An all-sky imager (ASI) records atmospheric emissions from zenith to low on the horizon at all azimuths, a region typically spanning millions of square kilometers. Each pixel (with its unique elevation, azimuth, and emission height) can be mapped along B-field lines to the equatorial plane of the magnetosphere. Auroral and subauroral structures and boundaries seen in emission within the ionosphere-thermosphere (I-T) system can thus be related to source regions. For a midlatitude site, this I-T to inner magnetosphere connection typically falls within the L = 2–5 earth radii domain. In this study, we present the first case of a stable auroral red (SAR) arc observed from three widely spaced ASI sites (Europe, North America, New Zealand). SAR arcs are produced during the main and recovery phases of a geomagnetic storm, with emission driven by heat conduction from a very specific location in the magnetosphere—the L value where the plasmapause and the inner edge of the ring current overlap. Using three-site observations, we show that this boundary can be followed for 24 consecutive hours. Simultaneous observations made by three satellites in the Defense Meteorological Satellite Program (DMSP) show that the lowest latitude peak in electron temperature can be used to map the same boundary. A key structure of the inner magnetosphere that cannot be observed continuously from sensors orbiting within the magnetosphere is made continuously visible to ground-based optical systems via effects caused by the drainage of small amounts of ring current energy into the I-T system.

Published
2013
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40. Vertical and meridional equatorial ion flows observed by CINDI during the 26 September 2011 storm

Author

Russell Stoneback, W. Robin Coley, and Marc R. Hairston

Subjects
Geomagnetic storm, Zonal and meridional, Storm, Geophysics, Plasma, Atmospheric sciences, Physics::Geophysics, Space and Planetary Science, Electric field, Physics::Space Physics, Polar, Ionosphere, Physics::Atmospheric and Oceanic Physics, Geology, Dynamo
Abstract

[1] The equatorial ionosphere is generally shielded from outside electrical fields except during large geomagnetic storms. During these storms, the polar region electric fields can temporarily extend to the equatorial regions in what is called a penetration field. During the subsequent recovery period, a disturbance dynamo is produced with an enhanced electric field with the opposite orientation relative to the penetration field. The penetration electric field would be oriented toward the east on the dayside causing an excess upward E × B motion of the equatorial ionospheric ions. The disturbance dynamo electric field would have the opposite orientation, westward on the dayside, producing an excess downward E × B motion of the equatorial ionospheric ions. The moderate storm (minimum Dst = −103 nT) on 26 September 2011 is examined using ion flow data from the Coupled Ion-Neutral Dynamics Investigation (CINDI) thermal plasma instrument package on the Communication/Navigation Outage Forecast System (C/NOFS) spacecraft on the dayside and early evening local times to look for examples of these flows. Despite what should have been a large enough storm to produce penetration fields and upward flows, a detailed examination of the observed flows from this storm shows only enhanced downward flows before the storm, during the main phase, and through the recovery.

Published
2013
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41. Field‐aligned current reconfiguration and magnetospheric response to an impulse in the interplanetary magnetic field B Y component

Author

C. J. Heinselman, Haje Korth, Stefan Eriksson, Frederick Wilder, Marc R. Hairston, Brian J. Anderson, and J. B. H. Baker

Subjects
Physics, Solar wind, Geophysics, Earth's magnetic field, Physics::Space Physics, Substorm, General Earth and Planetary Sciences, Magnetosphere, Magnetopause, Interplanetary magnetic field, Ionosphere, Thermosphere
Abstract

[1] When the interplanetary magnetic field (IMF) is dawnward or duskward, magnetic merging between the IMF and the geomagnetic field occurs near the cusp on the dayside flanks of the magnetosphere. During these intervals, flow channels in the ionosphere with velocities in excess of 2 km/s have been observed, which can deposit large amounts of energy into the high-latitude thermosphere. In this study, we analyze an interval on 5 April 2010 where there was a strong dawnward impulse in the IMF, followed by a gradual decay in IMF magnitude at constant clock angle. Data from the Sondrestrom incoherent scatter radar and the Defense Meteorological Satellite Program spacecraft were used to investigate ionospheric convection during this interval, and data from the Active Magnetospheric and Planetary Electrodynamics Response Experiment (AMPERE) were used to investigate the associated Field-Aligned Current (FAC) system. Additionally, data from AMPERE were used to investigate the time response of the dawnside FAC pair. We find there is a delay of approximately 1.25 h between the arrival of the dawnward IMF impulse at the magnetopause and strength of the dawnward FAC pair, which is comparable to substorm growth and expansion time scales under southward IMF. Additionally, we find at the time of the peak FAC, there is evidence of a reconfiguring four-sheet FAC system in the morning local time sector of the ionosphere. Additionally, we find an inverse correlation between the dawn FAC strength and both the solar wind Alfvenic Mach number and the SYM-H index. No statistically significant correlation between the FAC strength and the solar wind dynamic pressure was found.

Published
2013
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42. Large-scale quasiperiodic plasma bubbles: C/NOFS observations and causal mechanism

Author

O. de La Beaujardiere, R. F. Pfaff, Marc R. Hairston, Patrick A. Roddy, John O. Ballenthin, Chao Song Huang, and Donald E. Hunton

Subjects
Physics, Solar minimum, Gravitational wave, Bubble, Plasma, Geophysics, Mechanics, Instability, Physics::Fluid Dynamics, Space and Planetary Science, Quasiperiodic function, Physics::Space Physics, Seeding, Ionosphere
Abstract

[1] Large-scale periodic plasma bubbles are often observed by ionospheric radars and satellites. The seeding effect of atmospheric gravity waves has been widely used to explain the generation of periodic plasma bubbles. However, it has not been well understood where the seeding process occurs and how a series of plasma bubbles is triggered. In this study, we present the observations of equatorial plasma bubbles by the Communication/Navigation Outage Forecasting System (C/NOFS) satellite. We show examples of quasiperiodic plasma bubbles in the post-midnight sector, with nearly equal distance of 800–1000 km between adjacent bubbles, in 2008 under deep solar minimum conditions. The bubble chain covered a longitudinal range of ~7000 km between 00:00 and 04:00 LT. Quasiperiodic plasma bubbles were also measured by C/NOFS in the evening sector in 2011 during the ascending phase of the solar activity, and the longitudinal distance between adjacent bubbles was ~500 km. We propose a causal mechanism to explain the generation of quasiperiodic plasma bubbles. In this scenario, atmospheric gravity waves are generated near the sunset terminator and initiate the Rayleigh-Taylor instability there. The spatial (longitudinal) periodicity of plasma bubbles is determined by the temporal periodicity of the seeding gravity waves. A period of 15–30 min of the seeding gravity waves corresponds to a longitudinal separation of 500–1000 km between adjacent bubbles. This mechanism provides a reasonable explanation of the observed quasiperiodic plasma bubbles.

Published
2013
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43. Sounding of the plasmasphere by Mid-continent MAgnetoseismic Chain (McMAC) magnetometers

Author

L. I. Winkler, M. Reno, Marc R. Hairston, Jerry Goldstein, Mark B. Moldwin, Peter Chi, Christopher T. Russell, Mark J. Engebretson, Dong-Hun Lee, R. Dalrymple, B. Chen, J. L. Cruz-Abeyro, K. Yumoto, J. P. Gibson, and Ian R. Mann

Subjects
Physics, Electron density, Depth sounding, Geophysics, Space and Planetary Science, Field line, Ionization, Local time, Plasmasphere, Noon, Atmospheric sciences, Longitude
Abstract

[1] We present a statistical analysis on the plasmaspheric mass density derived from the field line resonance (FLR) observations by the Mid-continent MAgnetoseismic Chain (McMAC). McMAC consists of nine stations in the United States and Mexico along the 330° magnetic longitude, spanning L-values between 1.5 and 3.4. Using the gradient method and an automated procedure for FLR detection, we studied a full year of McMAC observations between July 2006 and June 2007. We find that the rate of FLR detection can reach as high as 56% around local noon at L = 2.7, and the detection rates at higher and lower L-values decline due to the occasional presence of the plasmapause and weaker FLR signals, respectively. At L-values between 1.8 and 3.1, the inferred equatorial plasma mass density follows the L-dependence of L−4. By comparing the mass density with the electron density, we found that the ion mass gradually decreased from 1.7 amu at L = 1.8 to 1 amu at L = 3.1. The plasma mass density exhibits an annual variation that maximizes in January, and at L = 2.4 the ratio between January and July densities is 1.6. Our observations also show a local time dependence of plasmaspheric mass density that stays steady in the morning and rises postnoon, a phenomenon that may be attributed to the equatorial ionization anomaly as a part of the plasma neutral coupling at low latitude.

Published
2013
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44. Long‐lasting daytime equatorial plasma bubbles observed by the C/NOFS satellite

Author

Donald E. Hunton, Marc R. Hairston, Chao Song Huang, Patrick A. Roddy, John O. Ballenthin, and O. de La Beaujardiere

Subjects
Geomagnetic storm, Physics, Daytime, Geophysics, Altitude, Space and Planetary Science, Storm, Plasma, Interplanetary magnetic field, Sunset, Atmospheric sciences, Dynamo
Abstract

[1] We report the first observations of long-lasting daytime equatorial plasma bubbles with the Communication/Navigation Outage Forecasting System (C/NOFS) satellite. The most unusual features of the plasma bubbles are the persistence from the post-midnight sector through the afternoon sector and the extremely long lifetime of 12 h. In one case, the plasma bubbles were generated at 02:00–03:00 LT near the end of the main phase of a moderate magnetic storm and detected by C/NOFS over eight successive orbits, and the decrease of the ion density inside the bubbles was still as large as ~30% at 14:00–15:00 LT. In another case, one group of plasma bubbles was generated near the sunset terminator and existed over the entire nighttime until the post-sunrise sector (06:00–08:00 LT), and another group of plasma bubbles was first detected at 04:00–06:00 LT and lasted until ~11:00 LT. The latter group of bubbles occurred following a sharp northward turning of the interplanetary magnetic field (IMF) near the end of the main phase of a weak magnetic storm, and the overshielding electric field caused by the IMF northward turning and the storm time disturbance dynamo might both have contributed to the generation of the bubbles. The plasma bubbles reached 800 km or higher in altitude during daytime. The high altitudes may be critical for the long lifetime of the bubbles: the photo-ionization rate decreases rapidly with altitude. The photo-ionization process may take a long time to produce enough new plasma particles to fill the daytime bubbles at high altitudes.

Published
2013
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45. Imaging space weather over Europe

Author

Massimo Materassi, J. Wroten, Carlos Martinis, Gabriele Umbriaco, Joe Kinrade, Cesare Barbieri, Marc R. Hairston, Luigi Ciraolo, Michael Mendillo, Cathryn N. Mitchell, and Jeffrey Baumgardner

Subjects
Geomagnetic storm, Atmospheric Science, Meteorology, Storm, Plasmasphere, Satellite, Space weather, Ionosphere, Geology, Ring current, Latitude
Abstract

[1] We describe the introduction of the first all-sky imaging system for low-light-level optical observations of the disturbed ionosphere over mid-latitude Europe. Using 6300 angstrom auroral emissions that come from the 200-400 km altitude range, we demonstrate that sub-visual optical patterns spanning the European continent can be obtained from a single site in Italy. Pilot observations during the 26-27 September 2011 geomagnetic storm show that the diffuse aurora's low latitude boundary can be used to find where the poleward wall of the ionospheric trough is located. This relates directly to regions of radiowave disruptions caused by the precipitation of energetic particles from the magnetospheric plasma sheet that move to lower latitudes during space weather events. Images of stable auroral red (SAR) arcs can be used to track the magnetospheric ring current and plasmapause location, a second region of radiowave interference. Comparisons with ground-based and satellite observations of the ionosphere during the same storm demonstrate how ASI images reveal the lowest energy components of magnetospheric input to the ionosphere-thermosphere system. Such observations can be used, potentially, for both now-casting of storm effects spanning Europe, and for retrospective validation of existing models of space weather impacts at sub-auroral locations. Citation: Baumgardner, J., et al. (2013), Imaging space weather over Europe, Space Weather, 11, 69-78, doi:10.1002/swe.20027.

Published
2013
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46. Responses in the polar and equatorial ionosphere to the March 2015 St. Patrick Day storm

Author

Marc R. Hairston, Russell Stoneback, and W. R. Coley

Subjects
010504 meteorology & atmospheric sciences, Spacecraft, Meteorology, business.industry, Equator, Storm, Atmospheric sciences, 01 natural sciences, Physics::Geophysics, Solar wind, Geophysics, Space and Planetary Science, Local time, Middle latitudes, Physics::Space Physics, 0103 physical sciences, Astrophysics::Earth and Planetary Astrophysics, Ionosphere, business, 010303 astronomy & astrophysics, Physics::Atmospheric and Oceanic Physics, Geology, 0105 earth and related environmental sciences, Dynamo
Abstract

The St. Patrick Day storm of 2015 (17 March 2015) occurred at a unique time when there were multiple spacecraft observing the Earth's ionosphere between 350 and 885 km. Observations of the plasma flows and densities from the five operational polar-orbiting DMSP spacecraft combined with those from the equatorial-orbiting C/NOFS spacecraft provided a comprehensive global record of the both the polar and equatorial ionosphere regions' responses to the storm. This paper presents an overview of the data from this suite of spacecraft focusing on the following aspects: (1) the polar cap ionosphere's reaction to the storm, (2) the change in the penetration electric field in the midlatitude region as a function of time and the solar local time during the storm, (3) the equatorial ionosphere's response of the meridional (vertical) flows to the penetration electric field and the disturbance dynamo during the storm, and (4) the creation of a predawn ionospheric bubble system near the equator during the storm's main phase that was observed at low altitudes by C/NOFS and later at high altitudes by several DMSP. Examining these phenomenon enable us to trace the dynamic flow of energy from the solar wind input in the polar ionosphere all the way to the equatorial ionosphere.

Published
2016
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47. Equatorial broad plasma depletions associated with the evening prereversal enhancement and plasma bubbles during the 17 March 2015 storm

Author

Larry J. Paxton, Geonhwa Jee, Hyosub Kil, Woo Kyoung Lee, and Marc R. Hairston

Subjects
010504 meteorology & atmospheric sciences, Polar orbit, Defense Meteorological Satellite Program, Storm, Geophysics, Plasma, 01 natural sciences, F region, Physics::Geophysics, Latitude, Space and Planetary Science, Electric field, Physics::Space Physics, 0103 physical sciences, Ionosphere, 010303 astronomy & astrophysics, Physics::Atmospheric and Oceanic Physics, Geology, 0105 earth and related environmental sciences
Abstract

Broad plasma depletions (BPDs) in the equatorial F region represent plasma depletions whose longitudinal and latitudinal scales are much greater than those of normal plasma bubbles. This study investigates the characteristics and origin of BPDs using the coincident ionospheric observations by the Communication/Navigation Outage Forecasting System, Defense Meteorological Satellite Program, and Swarm satellites during the 2015 St. Patrick's Day (17 March) storm. Two types of BPDs were detected before midnight during the main phase of the storm. One type of BPDs showed a gradual plasma density variation (Type 1), and the other type of BPDs showed a steep density gradient (Type 2) at the walls of BPDs. The Type 1 BPDs were detected with no signature of plasma bubbles nearby, whereas the Type 2 BPDs were accompanied by bubbles. The formation of the Type 1 BPDs is attributed to the uplift of the bottomside of the F region above the satellite altitude by the action of storm-induced electric fields. The steep walls of Type 2 BPDs are associated with the ionospheric uplift and the spatial discontinuity of the ionosphere produced by bubbles. The detection of BPDs that are more than 15° wide in latitude by the polar orbit Swarm satellites arises from the elongation of bubbles along the magnetic field lines and the alignment of the elongation with the plane of the orbit.

Published
2016
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48. Earth's ion upflow associated with polar cap patches: global and in-situ observations

Author

Malcolm Dunlop, Mike Lockwood, Yong C.-M. Liu, Rui Yuan Liu, M. Lester, Qing-He Zhang, Yu Zhang Ma, Roderick A. Heelis, Evan G. Thomas, Marc R. Hairston, J. Michael Ruohoniemi, Joran Moen, Shun-Rong Zhang, Yongliang Zhang, Qiugang Zong, Jun Liang, Bei-Chen Zhang, and Ian McCrea

Subjects
Geomagnetic storm, 010504 meteorology & atmospheric sciences, Defense Meteorological Satellite Program, Magnetosphere, Geophysics, Atmospheric sciences, 01 natural sciences, F region, 13. Climate action, Ionization, 0103 physical sciences, Physics::Space Physics, General Earth and Planetary Sciences, Outflow, Interplanetary magnetic field, Ionosphere, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences
Abstract

We report simultaneous global monitoring of a patch of ionization and in situ observation of ion upflow at the center of the polar cap region during a geomagnetic storm. Our observations indicate strong fluxes of upwelling O+ ions originating from frictional heating produced by rapid antisunward flow of the plasma patch. The statistical results from the crossings of the central polar cap region by Defense Meteorological Satellite Program F16–F18 from 2010 to 2013 confirm that the field-aligned flow can turn upward when rapid antisunward flows appear, with consequent significant frictional heating of the ions, which overcomes the gravity effect. We suggest that such rapidly moving patches can provide an important source of upwelling ions in a region where downward flows are usually expected. These observations give new insight into the processes of ionosphere-magnetosphere coupling.

Published
2016

49. Subauroral polarization streams: observations with the Hokkaido and King Salmon SuperDARN radars and modeling

Author

Yusuke Ebihara, D. André, Nozomu Nishitani, Marc R. Hairston, A. V. Koustov, and Takashi Kikuchi

Subjects
Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, STREAMS, King salmon, Atmospheric sciences, 01 natural sciences, law.invention, Latitude, law, 0103 physical sciences, Substorm, Earth and Planetary Sciences (miscellaneous), Radar, cvg, lcsh:Science, 010303 astronomy & astrophysics, Ring current, 0105 earth and related environmental sciences, cvg.computer_videogame, lcsh:QC801-809, Geology, Astronomy and Astrophysics, lcsh:QC1-999, lcsh:Geophysics. Cosmic physics, Space and Planetary Science, lcsh:Q, Ionosphere, Far East, lcsh:Physics
Abstract

The newly installed SuperDARN Hokkaido HF radar monitors ionospheric plasma flow between magnetic latitudes of 45° and 65° and thus has a great potential for studies of subauroral polarization streams (SAPS) in combination with another SuperDARN radar located at King Salmon, Alaska as well as the DMSP satellites and ground-based instruments in the Alaskan sector of the Arctic. Preliminary survey shows that although SAPS are often detected with the Hokkaido radar, their velocities are rather low, to the order of 150 m/s in its most suitable central beams. In this study, observations of unusually fast Hokkaido flows of up to 800 m/s are presented. The event of 1 April 2007 is investigated in detail. It is shown that high-velocity echoes appear after substorm onsets over North America with a delay of ~30 min. In terms of latitude, the velocity peaks just outside the auroral oval; signatures of a detached polarization jet are occasional and not pronounced. The King Salmon radar operating concurrently detects SAPS signatures as well but at different times and locations. Simulation with the Comprehensive Ring Current Model for the 1 April event reasonably identifies the period of fast flow occurrence but the velocity is underestimated. The event studied suggests that substorm-injected particle populations may intensify the pre-existing SAPS flow and lead to a mismatch of the predictions and observations.

Published
2008

50. Features of morning-time auroras during SC

Author

Marc R. Hairston, V. B. Belakhovsky, V. K. Roldugin, O. I. Yagodkina, and V. G. Vorobjev

Subjects
Convection, Drift velocity, Astrophysics::High Energy Astrophysical Phenomena, media_common.quotation_subject, Geophysics, Astrophysics, Luminosity, Earth's magnetic field, Quiet period, Space and Planetary Science, Sky, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Astrophysics::Earth and Planetary Astrophysics, Precipitation, Geology, Morning, media_common
Abstract

The optical observations on Heiss Island and the ion drift measurements on the DMSP F8 satellite were used to study the aurora characteristics and ionospheric convection before and after SC registered at 2330 UT on January 13, 1988. It has been indicated that two zones of luminosity can be distinguished in morning-time auroras during the quiet period before SC: the soft zone with auroral arcs and the harder diffuse auroral zone (equatorward of the first zone). After SC, a gradual smooth activation of auroras in both zones was followed (4–5 min later) by a more abrupt intensification of diffuse luminosity and by the appearance of numerous bright discrete auroras throughout the sky. In the diffuse auroral zone, the variations in the luminosity intensity with a period of 6–7 min were observed after SC. Auroral and geomagnetic field pulsations are closely correlated. During the quiet period before SC, sunward convection was concentrated in the soft precipitation region in the form of jets located in the vicinity of auroral arcs. After SC, considerable sunward convection was observed in the diffuse auroral zone. Peaks of the upward ion drift velocity were registered in the vicinity of auroral arcs.

Published
2008
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