Browse Articles
Quantifying the Sheath Impedance of the Electric Double Probe Instrument on the Van Allen Probes
-  27 April 2022
Key Points
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Variable coupling impedance between the instrument and plasma has been quantified for the electric field measurements on Van Allen Probes
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Sheath correction is demonstrated to substantially improve agreement between data and theoretical predictions from Faraday's Law
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Sheath-corrected EMFISIS L4 data set produced for archive. Full details are also provided to facilitate manual data corrections
Lower‐Hybrid Wave Structures and Interactions With Electrons Observed in Magnetotail Reconnection Diffusion Regions
-  26 April 2022
Key Points
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A dozen of magnetotail electron diffusion region with near-zero to 30% guide field are analyzed to establish lower-hybrid wave properties therein
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Electron temperature fluctuations due to electron acceleration and current sheet corrugation are correlated with the wave potential
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The electron pressure gradient contribution to the wavefield and electron vortices correlated with field line twisting are demonstrated
Multiple Reconnection X‐Lines at the Magnetopause and Overlapping Cusp Ion Injections
-  26 April 2022
Key Points
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Magnetospheric multiscale observations often show evidence of multiple reconnection at the magnetopause
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Twin Rocket Investigation of Cusp Electrodynamics-2 observations of overlapping cusp ion injections are also evidence of multiple reconnections at the magnetopause
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There is a strong link between multiple reconnections at the magnetopause and overlapping cusp ion dispersions
A 3D Physics‐Based Particle Model of the Venus Oxygen Corona: Variations With Solar Activity
-  25 April 2022
Key Points
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The density of Venus' extended oxygen corona varies almost by a factor of six of magnitude during a solar cycle
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Kinetic modeling reproduces PVO observations of Venus' “hot” oxygen corona when forward scattering of the energetic oxygen atoms is employed
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The strong dependence of the oxygen density in the corona from solar conditions suggested by results of our modeling is consistent with the non-detection of the oxygen corona from Venus Express conducted at solar minimum conditions
Fast Inverse Transform Sampling of Non‐Gaussian Distribution Functions in Space Plasmas
-  23 April 2022
Key Points
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New computational tool for fast sampling of arbitrary particle distribution functions is presented
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Chebyshev polynomial interpolation allows to approximate grid-based distributions and accelerates the solution of inversion problem
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We illustrate the use of Chebsampling via sampling non-Harris current sheets and non-Maxwellian velocity distributions
Detection of Equatorial Plasma Velocity Modulations Associated With Planetary Period Oscillations in Saturn's Magnetosphere
-  23 April 2022
Key Points
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We analyze a database of Cassini Saturn equatorial ion velocities 2004–2012 spanning 5.5–21.5 RS for planetary period oscillations (PPOs)
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Northern and southern PPOs are detected at amplitudes few to ∼10 km s–1 in the azimuthal but not in the radial or colatitudinal components
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Azimuthal flow phases are consistent with expectations for oscillations driven outward from the corresponding polar ionospheres
A Study of Post‐Sunset Spread‐F Initiation During the 2013 EVEX Campaign
-  23 April 2022
Key Points
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Radar backscatter observations monitor the ionospheric density irregularities developing in pre- and post-sunset equatorial E and F regions
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Two rockets launched into the equatorial ionosphere at sunset collect measurements of E- and F-region plasma drifts and neutral winds
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Links between the generation of post-sunset F-region turbulence and sunset time F-region winds within the plasma drift vortex are examined
The Effects of Solar Cycle Variability on Nanodust Dynamics in the Inner Heliosphere: Predictions for Future STEREO A/WAVES Measurements
-  23 April 2022
Key Points
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Inner heliospheric nanodust dynamics are modeled over a broad range of solar cycles and IMF polarity
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Cessation of single-hit impacts on STA/WAVES is correlated with model predictions of declining nanodust fluxes at 1 au
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We predict single-hit impacts due to nanodust impacts should gradually reappear in STA/WAVES between 2022 and 2028
Thank You to Our 2021 Reviewers
-  23 April 2022
Key Point
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The editors thank the 2021 peer reviewers
Electron‐scale current sheet as the boundary of a linear magnetic hole in the terrestrial current sheet observed by the Magnetospheric Multiscale mission
-  6 May 2022
Key Points
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We have studied the properties of a linear magnetic hole (LMH) with a size between typical ion and electron scales in the current sheet
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A thin current formed by a strong electron flow on the outermost boundary of the LMH wrap most of the trapped electrons
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The electric field occurs at the sharp boundary, possibly originating from the variation of the ion and electron gyrations at the boundary
Polar Cap Boundary identification using redline optical data and DMSP satellite particle data
-  6 May 2022
Key Points
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We compare the auroral poleward boundary determined using simultaneous optical and particle data during different geomagnetic conditions
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We find good agreement between the auroral boundary determined by auroral luminosity and those determined by particle flux
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Luminosity method can be applied during active geomagnetic conditions, providing high spatial and temporal resolution polar cap boundary
Resolving Vertical Variations of Horizontal Neutral Winds in Earth’s High Latitude Space‐Atmosphere Interaction Region (SAIR)
-  5 May 2022
Key Points
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We present height profiles of horizontal winds in the space-atmosphere interaction region where measurements have previously been difficult
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Height profiles from both this technique and chemical tracers are not consistent with the HWM-14 model
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Applying this approach to two years of data from two sites showed no indication of cusp-region forcing penetrating down to E-region heights
Time‐Dependent Electron Transport I Modelling of Supra‐thermal Electron Bursts modulated at 5–10 Hz with Implications for Flickering Aurora
-  4 May 2022
Key Points
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First Time-dependent multi-stream electron transport calculations are presented
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Intensity modulation variations for emissions at 4278, 6730, 7774 and 8448 Å during flickering aurora are compared
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Time-shift between column emission rates at 4278, 6730, 7774 and 8448 Å are predicted
Generation mechanisms of plasma density irregularity in the equatorial ionosphere during a geomagnetic storm on December 21 and 22, 2014
-  2 May 2022
Key Points
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The ROTI enhancement occurs three times over South America in the post-sunset, pre-midnight, and post-midnight sectors during the storm
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The ROTI enhancements appear with a longitudinal extent of ∼20° in the equatorial ionosphere
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The second ROTI enhancement is caused by the prompt penetration of an over-shielding electric field into the equator after a substorm
Relativistic electron precipitation driven by non‐linear resonance with whistler‐mode waves
-  2 May 2022
Key Points
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Intense near-equatorial whistler-mode waves are observed in conjunction with energetic electron precipitation measured by ELFIN
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Test particle simulations are employed to directly compare observations with theory of non-linear wave particle resonant interactions
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Precipitating electrons up to relativistic energies are likely due to resonant scattering extending up to 40° in latitude
Density Compressions at Magnetic Switchbacks Associated with Fast Plasma: A Superposed Epoch Analysis
-  2 May 2022
Key Points
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The properties associated with magnetic switchbacks evolve with radial distance
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Density compressions at the leading edge of switchbacks are correlated with velocity differences between fast plasma and ambient solar wind
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The density compressions associated with magnetic switchbacks are consistent with magnetic field surrounding a fast ejecta
Mesoscale spatial variability of lower thermospheric winds during the Anomalous Transport Rocket Experiment
-  30 April 2022
Key Points
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Seven simultaneous wind profiles in the lower thermosphere, horizontally separated by up to 600 km, are dominated by strong tides
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A large-scale upward propagating inertia-gravity wave is evident in the observations
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The region between 100 and 110 km shows the largest mesoscale variability of winds and wind shears, independent of separation scale
Study of slow‐mode shock formation and particle acceleration in the symmetric magnetic reconnection based on hybrid simulations
-  29 April 2022
Key Points
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Slow-mode shocks can be detected from ∼9 , and their detection increases with increasing plasma beta and the distance from the X-point
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The slow-mode shock detection percentage can drop to as low as ∼10% if the crossing angle of the satellite is very oblique
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Close to the X-point ( 45 ), the classical picture of slow-mode shocks is valid, as they directly accelerate the downstream population
Formation of the electron inflow along the separatrices during collisionless magnetic reconnection
-  27 April 2022
Key Points
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Electron inflow is accelerated by parallel electric field and mirror force, and decelerated by the gradient of parallel electron pressure
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Parallel electric field plays a major role in the formation of electron inflow, while the contribution of mirror force cannot be ignored
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The contributions of parallel electric field and mirror force change with the background plasma density and temperature
NRLMSISE‐00 empirical model of the atmosphere: Statistical comparisons and scientific issues
- Journal of Geophysical Research: Space Physics
-  SIA 15-1-SIA 15-16
-  24 December 2002
What is a geomagnetic storm?
- Journal of Geophysical Research: Space Physics
-  5771-5792
-  1 April 1994
Solar wind spatial scales in and comparisons of hourly Wind and ACE plasma and magnetic field data
- Journal of Geophysical Research: Space Physics
-  16 February 2005
Modeling the dynamics of the inner magnetosphere during strong geomagnetic storms
- Journal of Geophysical Research: Space Physics
-  15 March 2005
Collision frequency of artificial satellites: The creation of a debris belt
- Journal of Geophysical Research: Space Physics
-  2637-2646
-  1 June 1978
Magnetic loop behind an interplanetary shock: Voyager, Helios, and IMP 8 observations
- Journal of Geophysical Research: Space Physics
-  6673-6684
-  1 August 1981
The SuperMAG data processing technique
- Journal of Geophysical Research: Space Physics
-  14 September 2012
Key Points
- A weak residual ring current is always present
- Automated baseline determination technique
- Determination of local magnetic coordinate system
Magnetopause location under extreme solar wind conditions
- Journal of Geophysical Research: Space Physics
-  17691-17700
-  1 August 1998
Geospace Environmental Modeling (GEM) Magnetic Reconnection Challenge
- Journal of Geophysical Research: Space Physics
-  3715-3719
-  1 March 2001
The ionospheric disturbance dynamo
- Journal of Geophysical Research: Space Physics
-  1669-1686
-  1 April 1980
Quasi two day wave‐related variability in the background dynamics and composition of the mesosphere/thermosphere and the ionosphere
- Journal of Geophysical Research: Space Physics
-  4786-4804
-  15 May 2014
Key Points
- Dissipating planetary waves (PWs) in the MLT can drive background wind changes
- Mixing from dissipating PWs drive thermosphere/ionosphere composition changes
- First observations of QTDW-driven variability from this mechanism
Effect of the altitudinal variation of the gravitational acceleration on the thermosphere simulation
- Journal of Geophysical Research: Space Physics
-  4 September 2008
SWAN/SOHO Lyman‐α Mapping: The Hydrogen Geocorona Extends Well Beyond the Moon
- Journal of Geophysical Research: Space Physics
-  861-885
-  15 February 2019
Key Points
- We find that the geocorona extends to almost twice the distance of the Moon
- the H exosphere is compressed by solar radiation pressure, forming a bulge on the dayside
- this bulge is enhanced at low solar activity, possibly in relation with a population of Hatoms in satellite orbits
Earth's Van Allen Radiation Belts: From Discovery to the Van Allen Probes Era
- Journal of Geophysical Research: Space Physics
-  8319-8351
-  23 November 2019
Key Points
- A brief historical background on the discovery of the Van Allen radiation belts and their response to solar activity is introduced
- Recent advances in understanding mechanisms responsible for radiation belt electron acceleration, transport, and loss are reviewed
- Outstanding challenges for developing future radiation belt models are summarized
Plain Language Summary
Discovery of the Earth's Van Allen radiation belts by instruments flown on Explorer 1 in 1958 was the first major discovery of the Space Age. The dynamic properties of trapped outer zone electrons and the outer boundary of the inner zone proton population, along with source populations, have recently been studied in great detail by instruments on National Aeronautics and Space Administration's Van Allen Probes spacecraft, as well as other data sources like operational spacecraft designed for navigation and terrestrial weather forecasting. The vulnerability of the myriad of spacecraft that is strongly affected by space weather disruptions, as compared to 1958, has motivated the radiation belt community to develop essential improved models for forecasting the space environment we will inhabit in the 21st century and evaluate its impacts on our technological society. In this paper, we provide a review on historical background and recent advances in understanding and modeling acceleration, transport, and loss processes of energetic particles in the Earth's Van Allen radiation belts, followed by outstanding challenges for developing future radiation belt models. The findings on the fundamental physics of the Van Allen radiation belts potentially provide insights into understanding energetic particle dynamics at other magnetized planets in the solar system, exoplanets throughout the universe, as well as in astrophysical and laboratory plasmas. Given the potential Space Weather impact of radiation belt variability on technological systems, these new radiation belt models are expected to play a critical role in our technological society in the future much as meteorological models do today.
Diurnal nonmigrating tides from TIMED Doppler Interferometer wind data: Monthly climatologies and seasonal variations
- Journal of Geophysical Research: Space Physics
-  9 September 2006
Low‐frequency waves and instabilities in stratified, gyrotropic, multicomponent plasmas: Theory and application to plasma transport in the Io torus
- Journal of Geophysical Research: Space Physics
-  28 December 2004
NRLMSISE‐00 empirical model of the atmosphere: Statistical comparisons and scientific issues
- Journal of Geophysical Research: Space Physics
-  SIA 15-1-SIA 15-16
-  24 December 2002
Magnetic Reconnection in the Space Sciences: Past, Present, and Future
- Journal of Geophysical Research: Space Physics
-  15 December 2019
Key Points
- Magnetic reconnection is a key energy conversion and transport process in plasmas
- There has been recent, considerable, research progress understanding how reconnection works
- Many exciting research challenges await, while we can reap the benefits of our new understanding
Plain Language Summary
In space, huge amounts of energy are released explosively by a mysterious mechanism: magnetic reconnection. Reconnection can abruptly convert energy stored in magnetic fields to energy in charged particles, and power such diverse phenomena as solar and stellar flares, magnetic storms and aurorae in near-Earth space, and major disruptions in magnetically confined fusion devices. It is behind many of the dangerous effects associated with space weather, including damage to satellites, endangering astronauts, and impacting the power grid and pipelines. Understanding reconnection enables us to quantitatively describe and predict these magnetic explosions. Therefore, magnetic reconnection has been at the forefront of scientific interest for many years, and will be for many more. Measuring reconnection is incredibly difficult. However, recently scientists have been able to peek into its machinery. Combining measurements from NASA's Magnetospheric Multiscale mission with supercomputer modeling, scientists have now been able to analyze the inner workings of this elusive mechanism. Even though open questions remain, this new understanding has broad implications. Here, we describe magnetic reconnection, where it plays a role, its impacts on society, and what we now know about it. We point to future research challenges, including implications and the utility of our recently developed knowledge.
Possible modification of the cooling index of interstellar helium pickup ions by electron impact ionization in the inner heliosphere
- Journal of Geophysical Research: Space Physics
-  7142-7150
-  7 September 2014
Key Points
- The influence of electron impact ionization is negligible
- Its influence is also small even in the compressions
Editorial: Reviewer selection process and new areas of expertise in GEMS
- Journal of Geophysical Research: Space Physics
-  5566-5570
-  23 May 2016
Key Points
- Methods for selecting potential reviewers for manuscripts are described, including filtering user Areas of Expertise in the GEMS database
- The Journal Editors have just added 18 new Areas of Expertise in GEMS, increasing the list by 33% to 73 entries
- Space physicists are urged to update their GEMS profiles, especially their Areas of Expertise, to improve potential reviewer selection