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2. Observations of Asymmetric Lobe Convection for Weak and Strong Tail Activity

Author

Ohma, A., Østgaard, N., Reistad, J. P., Tenfjord, P., Laundal, K. M., Jørgensen, T. Moretto, Haaland, S. E., Krcelic, P., and Milan, S.

Subjects
Physics - Space Physics
Abstract

In this study we use high-quality convection data from the Electron Drift Instrument on board Cluster to investigate how near-Earth tail activity affects the average convection pattern in the magnetotail lobes when the interplanetary magnetic field has a dominating east-west (B$_{y}$) component. Two different proxies have been used to represent different levels of reconnection in the near-Earth tail: The value of the AL index and the substorm phases identified by the Substorm Onsets and Phases from Indices of the Electrojet algorithm. We find that the convection changes from a dominantly Y$_{GSM}$direction, but opposite in the two hemispheres, to a flow oriented more toward the plasma sheet, as the north-south component of the convection increases when reconnection enhances in the near Earth tail. This result is consistent with recent observations of the convection in the ionosphere, which suggest that the nightside convection pattern becomes more north-south symmetric when tail reconnection increases. This is also supported by simultaneous auroral observations from the two hemispheres, which shows that conjugate auroral features become more symmetric during substorm expansion phase. The reduced asymmetry implies that the asymmetric pressure balance in the lobes is altered during periods with strong reconnection in the near-Earth tail.

Published
2021
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3. Characteristics of the Flank Magnetopause: THEMIS Observations

Author

Haaland, S., Runov, A., Artemyev, A., and Angelopoulos, V.

Subjects
Physics - Space Physics
Abstract

The terrestrial magnetopause is the boundary that shields the Earth's magnetosphere on one side from the shocked solar wind and its embedded interplanetary magnetic field on the other side. In this paper, we show observations from two of the Time History of Events and Macroscales Interactions during Substorms (THEMIS) satellites, comparing dayside magnetopause crossings with flank crossings near the terminator. Macroscopic properties such as current sheet thickness, motion, and current density are examined for a large number of magnetopause crossings. The results show that the flank magnetopause is typically thicker than the dayside magnetopause and has a lower current density. Consistent with earlier results from Cluster observations, we also find a persistent dawn-dusk asymmetry with a thicker and more dynamic magnetopause at dawn than at dusk.

Published
2020
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4. Prediction and understanding of soft proton contamination in XMM-Newton: a machine learning approach

Author

Kronberg, E. A., Gastaldello, F., Haaland, S., Smirnov, A., Berrendorf, M., Ghizzardi, S., Kuntz, K. D., Sivadas, N., Allen, R. C., Tiengo, A., Ilie, R., Huang, Y., and Kistler, L.

Subjects
Astrophysics - Instrumentation and Methods for Astrophysics, Physics - Space Physics
Abstract

One of the major and unfortunately unforeseen sources of background for the current generation of X-ray telescopes are few tens to hundreds of keV (soft) protons concentrated by the mirrors. One such telescope is the European Space Agency's (ESA) X-ray Multi-Mirror Mission (XMM-Newton). Its observing time lost due to background contamination is about 40\%. This loss of observing time affects all the major broad science goals of this observatory, ranging from cosmology to astrophysics of neutron stars and black holes. The soft proton background could dramatically impact future large X-ray missions such as the ESA planned Athena mission (http://www.the-athena-x-ray-observatory.eu/). Physical processes that trigger this background are still poorly understood. We use a Machine Learning (ML) approach to delineate related important parameters and to develop a model to predict the background contamination using 12 years of XMM observations. As predictors we use the location of satellite, solar and geomagnetic activity parameters. We revealed that the contamination is most strongly related to the distance in southern direction, $Z$, (XMM observations were in the southern hemisphere), the solar wind radial velocity and the location on the magnetospheric magnetic field lines. We derived simple empirical models for the first two individual predictors and an ML model which utilizes an ensemble of the predictors (Extra Trees Regressor) and gives better performance. Based on our analysis, future missions should minimize observations during times associated with high solar wind speed and avoid closed magnetic field lines, especially at the dusk flank region in the southern hemisphere., Comment: 20 pages, 11 figures

Published
2020
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5. Separation and Quantification of Ionospheric Convection Sources: 1. A New Technique

Author

Reistad, J. P., Laundal, K. M., Østgaard, N., Ohma, A., Haaland, S., Oksavik, K., and Milan, S. E.

Subjects
Physics - Space Physics
Abstract

This paper describes a novel technique that allows separation and quantification of different sources of convection in the high-latitude ionosphere. To represent the ionospheric convection electric field, we use the Spherical Elementary Convection Systems representation. We demonstrate how this technique can separate and quantify the contributions from different magnetospheric source regions to the overall ionospheric convection pattern. The technique is in particular useful for distinguishing the contributions of high-latitude reconnection associated with lobe cells from the low-latitude reconnection associated with Dungey two-cell circulation. The results from the current paper are utilized in a companion paper (Reistad et al., 2019, https://doi.org/10.1029/2019JA026641) to quantify how the dipole tilt angle influences lobe convection cells. We also describe a relation bridging other representations of the ionospheric convection electric field or potential to the Spherical Elementary Convection Systems description, enabling a similar separation of convection sources from existing models.

Published
2020
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6. How the IMF $\mathit{B}_{y}$ Induces a Local $\mathit{B}_{y}$ Component During Northward IMF $\mathit{B}_{z}$ and Characteristic Timescales

Author

Tenfjord, P., Østgaard, N., Haaland, S., Snekvik, K., Laundal, K. M., Reistad, J. P., Strangeway, R., Milan, S. E., Hesse, M., and Ohma, A.

Subjects
Physics - Space Physics
Abstract

We use the Lyon-Fedder-Mobarry global magnetohydrodynamics model to study the effects of the interplanetary magnetic field (IMF) $\mathit{B}_{y}$ component on the coupling between the solar wind and magnetosphere-ionosphere system when IMF $\mathit{B}_{z}$ $>$0. We describe the evolution of how a magnetospheric $\mathit{B}_{y}$ component is induced on closed field lines during these conditions. Starting from dayside lobe reconnection, the magnetic tension on newly reconnected field lines redistribute the open flux asymmetrically between the two hemispheres. This results in asymmetric magnetic energy density in the lobes. Shear flows are induced to restore equilibrium, and these flows are what effectively induces a local $\mathit{B}_{y}$ component. We show the radial dependence of the induced $\mathit{B}_{y}$ and compare the results to the induced $\mathit{B}_{y}$ during southward IMF conditions. We also show the response and reconfiguration time of the inner magnetosphere to IMF $\mathit{B}_{y}$ reversals during northward IMF $\mathit{B}_{z}$. A superposed epoch analysis of magnetic field measurements from seven Geostationary Operational Environmental Satellite spacecraft at different local times both for negative-to-positive and positive-to-negative IMF $\mathit{B}_{y}$ reversals is presented. We find that the induced $\mathit{B}_{y}$ responds within 16 min of the arrival of IMF $\mathit{B}_{y}$ at the bow shock, and it completely reconfigures within 47 min.

Published
2018
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7. Observations of Asymmetries in Ionospheric Return Flow During Different Levels of Geomagnetic Activity

Author

Reistad, J. P., Østgaard, N., Laundal, K. M., Ohma, A., Snekvik, K., Tenfjord, P., Grocott, A., Oksavik, K., Milan, S. E., and Haaland, S.

Subjects
Physics - Space Physics
Abstract

It is known that the magnetic field of the Earth's closed magnetosphere can be highly displaced from the quiet-day configuration when interacting with the interplanetary magnetic field (IMF), an asymmetry largely controlled by the dawn-dusk component of the IMF. The corresponding ionospheric convection has revealed that footprints in one hemisphere tend to move faster to reduce the displacement, a process we refer to as the restoring of symmetry. Although the influence on the return flow convection from the process of restoring symmetry has been shown to be strongly controlled by the IMF, the influence from internal magnetospheric processes has been less investigated. We use 14 years of line-of-sight measurements of the ionospheric plasma convection from the Super Dual Auroral Radar Network to produce high-latitude convection maps sorted by season, IMF, and geomagnetic activity. We find that the restoring symmetry flows dominate the average convection pattern in the nightside ionosphere during low levels of magnetotail activity. For increasing magnetotail activity, signatures of the restoring symmetry process become less and less pronounced in the global average convection maps. We suggest that tail reconnection acts to reduce the asymmetric state of the closed magnetosphere by removing the asymmetric pressure distribution in the tail set up by the IMF $\mathit{B}_{y}$ interaction. During active periods the nightside magnetosphere will therefore reach a more symmetric configuration on a global scale. These results are relevant for better understanding the dynamics of flux tubes in the asymmetric geospace, which is the most common state of the system.

Published
2018
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8. Characteristics of the Flank Magnetopause: THEMIS Observations.

Author

Haaland, S, Runov, A, Artemyev, A, and Angelopoulos, V

Subjects
Astronomical and Space Sciences, Atmospheric Sciences
Abstract

The terrestrial magnetopause is the boundary that shields the Earth's magnetosphere on one side from the shocked solar wind and its embedded interplanetary magnetic field on the other side. In this paper, we show observations from two of the Time History of Events and Macroscales Interactions during Substorms (THEMIS) satellites, comparing dayside magnetopause crossings with flank crossings near the terminator. Macroscopic properties such as current sheet thickness, motion, and current density are examined for a large number of magnetopause crossings. The results show that the flank magnetopause is typically thicker than the dayside magnetopause and has a lower current density. Consistent with earlier results from Cluster observations, we also find a persistent dawn-dusk asymmetry with a thicker and more dynamic magnetopause at dawn than at dusk.

Published
2019

9. Dayside and nightside magnetic field responses at 780 km altitude to dayside reconnection

Author

Snekvik, K., Østgaard, N., Tenfjord, P., Reistad, J. P., Laundal, K. M., Milan, S. E., and Haaland, S. E.

Subjects
Physics - Space Physics
Abstract

During southward interplanetary magnetic field, dayside reconnection will drive the Dungey cycle in the magnetosphere, which is manifested as a two-cell convection pattern in the ionosphere. We address the response of the ionospheric convection to changes in the dayside reconnection rate by examining magnetic field perturbations at 780 km altitude. The Active Magnetosphere and Planetary Electrodynamics Response Experiment data products derived from the Iridium constellation provide global maps of the magnetic field perturbations. Cluster data just upstream of the Earth's bow shock have been used to estimate the dayside reconnection rate. By using a statistical model where the magnetic field can respond on several time scales, we confirm previous reports of an almost immediate response both near noon and near midnight combined with a 10-20 min reconfiguration time of the two-cell convection pattern. The response of the ionospheric convection has been associated with the expansion of the polar cap boundary in the Cowley-Lockwood paradigm. In the original formulation of this paradigm the expansion spreads from noon to midnight in 15-20 min. However, also an immediate global response has been shown to be consistent with the paradigm when the previous dayside reconnection history is considered. In this paper we present a new explanation for how the immediate response can be accommodated in the Cowley-Lockwood paradigm. The new explanation is based on how MHD waves propagate in the magnetospheric lobes when newly reconnected open flux tubes are added to the lobes, and the magnetopause flaring angle increases.

Published
2017
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10. North-south asymmetries in cold plasma density in the magnetotail lobes: Cluster observations

Author

Haaland, S., Lybekk, B., Maes, L., Laundal, K., Pedersen, A., Tenfjord, P., Ohma, A., Østgaard, N., Reistad, J., and Snekvik, K.

Subjects
Physics - Space Physics
Abstract

In this paper, we present observations of cold (0-70 eV) plasma density in the magnetotail lobes. The observations and results are based on 16 years of Cluster observation of spacecraft potential measurements converted into local plasma densities. Measurements from all four Cluster spacecraft have been used, and the survey indicates a persistent asymmetry in lobe density, with consistently higher cold plasma densities in the northern lobe. External influences, such as daily and seasonal variations in the Earth's tilt angle, can introduce temporary north-south asymmetries through asymmetric ionization of the two hemispheres. Likewise, external drivers, such as the orientation of the interplanetary magnetic field can set up additional spatial asymmetries in outflow and lobe filling. The persistent asymmetry reported in this paper is also influenced by these external factors but is mainly caused by differences in magnetic field configuration in the Northern and Southern Hemisphere ionospheres.

Published
2017
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11. Dawn-dusk asymmetries in the coupled solar wind-magnetosphere-ionosphere system: a review

Author

Walsh, A. P., Haaland, S., Forsyth, C., Keesee, A. M., Kissinger, J., Li, K., Runov, A., Soucek, J., Walsh, B. M., Wing, S., and Taylor, M. G. G. T.

Subjects
Physics - Space Physics
Abstract

Dawn-dusk asymmetries are ubiquitous features of the coupled solar-wind-magnetosphere-ionosphere system. During the last decades, increasing availability of satellite and ground-based measurements has made it possible to study these phenomena in more detail. Numerous publications have documented the existence of persistent asymmetries in processes, properties and topology of plasma structures in various regions of geospace. In this paper, we present a review of our present knowledge of some of the most pronounced dawn-dusk asymmetries. We focus on four key aspects: (1) the role of external influences such as the solar wind and its interaction with the Earth's magnetosphere; (2) properties of the magnetosphere itself; (3) the role of the ionosphere and (4) feedback and coupling between regions. We have also identified potential inconsistencies and gaps in our understanding of dawn-dusk asymmetries in the Earth's magnetosphere and ionosphere.

Published
2017
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12. North-South Asymmetries in Earth's Magnetic Field: Effects on High-Latitude Geospace

Author

Laundal, K. M., Cnossen, I., Milan, S. E., Haaland, S. E., Coxon, J., Pedatella, N. M., Förster, M., and Reistad, J. P.

Subjects
Physics - Space Physics
Abstract

The solar-wind magnetosphere interaction primarily occurs at altitudes where the dipole component of Earth's magnetic field is dominating. The disturbances that are created in this interaction propagate along magnetic field lines and interact with the ionosphere-thermosphere system. At ionospheric altitudes, the Earth's field deviates significantly from a dipole. North-South asymmetries in the magnetic field imply that the magnetosphere ionosphere-thermosphere (M-I-T) coupling is different in the two hemispheres. In this paper we review the primary differences in the magnetic field at polar latitudes, and the consequences that these have for the M-I-T coupling. We focus on two interhemispheric differences which are thought to have the strongest effects: 1) A difference in the offset between magnetic and geographic poles in the Northern and Southern Hemispheres, and 2) differences in the magnetic field strength at magnetically conjugate regions. These asymmetries lead to differences in plasma convection, neutral winds, total electron content, ion outflow, ionospheric currents and auroral precipitation.

Published
2016
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13. Dynamic effects of restoring footpoint symmetry on closed magnetic field lines

Author

Reistad, J. P., Østgaard, N., Tenfjord, P., Laundal, K. M., Snekvik, K., Haaland, S., Milan, S. E., Oksavik, K., Frey, H. U., and Grocott, A.

Subjects
Physics - Space Physics
Abstract

Here we present an event where simultaneous global imaging of the aurora from both hemispheres reveals a large longitudinal shift of the nightside aurora of about 3 h, being the largest relative shift reported on from conjugate auroral imaging. This is interpreted as evidence of closed field lines having very asymmetric footpoints associated with the persistent positive $\textit{y}$ component of the interplanetary magnetic field before and during the event. At the same time, the Super Dual Auroral Radar Network observes the ionospheric nightside convection throat region in both hemispheres. The radar data indicate faster convection toward the dayside in the dusk cell in the Southern Hemisphere compared to its conjugate region. We interpret this as a signature of a process acting to restore symmetry of the displaced closed magnetic field lines resulting in flux tubes moving faster along the banana cell than the conjugate orange cell. The event is analyzed with emphasis on Birkeland currents (BC) associated with this restoring process, as recently described by Tenfjord et al. (2015). Using data from the Active Magnetosphere and Planetary Electrodynamics Response Experiment (AMPERE) during the same conditions as the presented event, the large-scale BC pattern associated with the event is presented. It shows the expected influence of the process of restoring symmetry on BCs. We therefore suggest that these observations should be recognized as being a result of the dynamic effects of restoring footpoint symmetry on closed field lines in the nightside.

Published
2016
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14. Birkeland current effects on high-latitude groundmagnetic field perturbations

Author

Laundal, K. M., Haaland, S. E., Lehtinen, N., Gjerloev, J. W., Østgaard, N., Tenfjord, P., Reistad, J. P., Snekvik, K., Milan, S. E., Ohtani, S., and Anderson, B. J.

Subjects
Physics - Space Physics
Abstract

Magnetic perturbations on ground at high latitudes are directly associated only with the divergence-free component of the height-integrated horizontal ionospheric current, $\textbf{J}_{\perp,df}$. Here we show how $\textbf{J}_{\perp,df}$ can be expressed as the total horizontal current $\textbf{J}_\perp$ minus its curl-free component, the latter being completely determined by the global Birkeland current pattern. Thus in regions where $\textbf{J}_\perp = 0$, the global Birkeland current distribution alone determines the local magnetic perturbation. We show with observations from ground and space that in the polar cap, the ground magnetic field perturbations tend to align with the Birkeland current contribution in darkness but not in sunlight. We also show that in sunlight, the magnetic perturbations are typically such that the equivalent overhead current is anti-parallel to the convection, indicating that the Hall current system dominates. Thus the ground magnetic field in the polar cap relates to different current systems in sunlight and in darkness.

Published
2016
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15. Distribution of energetic oxygen and hydrogen in the near-Earth plasma sheet

Author

Kronberg, E. A., Grigorenko, E. E., Haaland, S. E., Daly, P. W., Delcourt, D. C., Luo, H., Kistler, L. M., and Dandouras, I.

Subjects
Physics - Space Physics
Abstract

The spatial distributions of different ion species are useful indicators for plasma sheet dynamics. In this statistical study based on 7 years of Cluster observations, we establish the spatial distributions of oxygen ions and protons at energies from 274 to 955 keV, depending on geomagnetic and solar wind (SW) conditions. Compared with protons, the distribution of energetic oxygen has stronger dawn-dusk asymmetry in response to changes in the geomagnetic activity. When the interplanetary magnetic field (IMF) is directed southward, the oxygen ions show significant acceleration in the tail plasma sheet. Changes in the SW dynamic pressure ($\mathit{P}_{dyn}$) affect the oxygen and proton intensities in the same way. The energetic protons show significant intensity increases at the near-Earth duskside during disturbed geomagnetic conditions, enhanced SW $\mathit{P}_{dyn}$, and southward IMF, implying there location of effective inductive acceleration mechanisms and a strong duskward drift due to the increase of the magnetic field gradient in the near-Earth tail. Higher losses of energetic ions are observed in the dayside plasma sheet under disturbed geomagnetic conditions and enhanced SW $\mathit{P}_{dyn}$. These observations are in agreement with theoretical models.

Published
2016
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16. Characteristics of the flankmagnetopause: Cluster observations

Author

Haaland, S., Reistad, J., Tenfjord, P., Gjerloev, J., Maes, L., DeKeyser, J., Maggiolo, R., Anekallu, C., and Dorville, N.

Subjects
Physics - Space Physics
Abstract

The magnetopause is a current sheet forming the boundary between the geomagnetic field on one side and the shocked solar wind on the other side. This paper discusses properties of the low-latitude dawn and dusk flanks of the magnetopause. The reported results are based on a large number of measurements obtained by the Cluster satellites during magnetopause traversals. Using a combination of single-spacecraft and multispacecraft techniques, we calculated macroscopic features such as thickness, location, and motion of the magnetopause. The results show that the typical flank magnetopause is significantly thicker than the dayside magnetopause and also possesses a pronounced and persistent dawn-dusk asymmetry. Thicknesses vary from 150 to 5000 km, with an median thickness of around 1400 km at dawn and around 1150 km at dusk. Current densities are on average higher on dusk, suggesting that the total current at dawn and dusk are similar. Solar wind conditions and the interplanetary magnetic field cannot fully explain the observed dawn-dusk asymmetry. For a number of crossings we were also able to derive detailed current density profiles. The profiles show that the magnetopause often consists of two or more adjacent current sheets, each current sheet typically several ion gyroradii thick and often with different current direction. This demonstrates that the flank magnetopause has a structure that is more complex than the thin, one-dimensional current sheet described by a Chapman-Ferraro layer.

Published
2016
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17. Intensity asymmetries in the dusk sector of the poleward auroral oval due to IMF $\mathit{B}_{x}$

Author

Reistad, J. P., Østgaard, N., Laundal, K. M., Haaland, S., Tenfjord, P., Snekvik, K., Oksavik, K., and Milan, S. E.

Subjects
Physics - Space Physics
Abstract

In the exploration of global-scale features of the Earth's aurora, little attention has been given to the radial component of the Interplanetary Magnetic Field (IMF). This study investigates the global auroral response in both hemispheres when the IMF is southward and lies in the $\textit{xz}$ plane. We present a statistical study of the average auroral response in the 12-24 magnetic local time (MLT) sector to an $\textit{x}$ component in the IMF. Maps of auroral intensity in both hemispheres for two IMF $\mathit{B}_{x}$ dominated conditions($ \pm $ IMF $\mathit{B}_{x}$) are shown during periods of negative IMF $\mathit{B}_{z}$, small IMF $\mathit{B}_{y}$, and local winter. This is obtained by using global imaging from the Wideband Imaging Camera on the IMAGE satellite. The analysis indicates a significant asymmetry between the two IMF $\mathit{B}_{x}$ dominated conditions in both hemispheres. In the Northern Hemisphere the aurora is brighter in the 15-19 MLT region during negative IMF $\mathit{B}_{x}$. In the Southern Hemisphere the aurora is brighter in the 16-20 MLT sector during positive IMF $\mathit{B}_{x}$. We interpret the results in the context of a more efficient solar wind dynamo in one hemisphere. Both the intensity asymmetry and its location are consistent with this idea. This has earlier been suggested from case studies of simultaneous observations of the aurora in both hemispheres, but hitherto never been observed to have a general impact on global auroral brightness in both hemispheres from a statistical study. The observed asymmetries between the two IMF $\mathit{B}_{x}$ cases are not large; however, the difference is significant with a 95% confidence level. As the solar wind conditions examined in the study are rather common (37% of the time) the accumulative effect of this small influence may be important for the total energy budget.

Published
2016
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18. Solar illumination control of ionospheric outflow above polar cap arcs

Author

Maes, L., Maggiolo, R., De Keyser, J., Dandouras, I., Fear, R. C., Fontaine, D., and Haaland, S.

Subjects
Physics - Space Physics
Abstract

We measure the flux density, composition, and energy of outflowing ions above the polar cap, accelerated by quasi-static electric fields parallel to the magnetic field and associated with polar cap arcs, using Cluster. Mapping the spacecraft position to its ionospheric foot point, we analyze the dependence of these parameters on the solar zenith angle (SZA). We find a clear transition at SZA between We find a clear transition at SZA between $\sim$94$^{\circ}$ and $\sim$107$^{\circ}$, with the O$^{+}$ flux higher above the sunlit ionosphere. This dependence on the illumination of the local ionosphere indicates that significant O$^{+}$ upflow occurs locally above the polar ionosphere. The same is found for H$^{+}$, but to a lesser extent. This effect can result in a seasonal variation of the total ion upflow from the polar ionosphere. Furthermore, we show that low-magnitude field-aligned potential drops are preferentially observed above the sunlit ionosphere, suggesting a feedback effect of ionospheric conductivity.

Published
2016
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19. How the IMF $\mathit{B}_{y}$ induces a $\mathit{B}_{y}$ component in the closed magnetosphere and how it leads to asymmetric currents and convection patterns in the two hemispheres

Author

Tenfjord, P., Østgaard, N., Snekvik, K., Laundal, K. M., Reistad, J. P., Haaland, S., and Milan, S. E.

Subjects
Physics - Space Physics
Abstract

We used the Lyon-Fedder-Mobarry global magnetohydrodynamics model to study the effects of the interplanetary magnetic field (IMF) IMF $\mathit{B}_{y}$ component on the coupling between the solar wind and magnetosphere-ionosphere system. When the IMF reconnects with the terrestrial magnetic field with IMF $\mathit{B}_{y}$ $\neq$ 0, flux transport is asymmetrically distributed between the two hemispheres. We describe how $\mathit{B}_{y}$ is induced in the closed magnetosphere on both the dayside and nightside and present the governing equations. The magnetosphere imposes asymmetric forces on the ionosphere, and the effects on the ionospheric flow are characterized by distorted convection cell patterns, often referred to as "banana" and "orange" cell patterns. The flux asymmetrically added to the lobes results in a non-uniform induced $\mathit{B}_{y}$ in the closed magnetosphere. By including the dynamics of the system, we introduce a mechanism that predicts asymmetric Birkeland currents at conjugate foot points. Asymmetric Birkeland currents are created as a consequence of $\textit {y}$ directed tension contained in the return flow. Associated with these currents, we expect fast localized ionospheric azimuthal flows present in one hemisphere but not necessarily in the other. We also present current density measurements from Active Magnetosphere and Planetary Electrodynamics Response Experiment that are consistent with this picture. We argue that the induced $\mathit{B}_{y}$ produces asymmetrical Birkeland currents as a consequence of asymmetric stress balance between the hemispheres. Such an asymmetry will also lead to asymmetrical foot points and asymmetries in the azimuthal flow in the ionosphere. These phenomena should therefore be treated in a unified way.

Published
2016
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20. The impact of sunlight on high-latitude equivalent currents

Author

Laundal, K. M., Gjerloev, J. W., Østgaard, N., Reistad, J. P., Haaland, S., Snekvik, K., Tenfjord, P., Ohtani, S., and Milan, S. E.

Subjects
Physics - Space Physics
Abstract

Ground magnetic field measurements can be mathematically related to an overhead ionospheric equivalent current. In this study we look in detail at how the global equivalent current, calculated using more than 30 years of SuperMAG magnetometer data, changes with sunlight conditions. The calculations are done using spherical harmonic analysis in quasi-dipole coordinates, a technique which leads to improved accuracy compared to previous studies. Sorting the data according to the location of the sunlight terminator and orientation of the interplanetary magnetic field (IMF), we find that the equivalent current resembles ionospheric convection patterns on the sunlit side of the terminator but not on the dark side. On the dark side, with southward IMF, the current is strongly dominated by a dawn cell and the current across the polar cap has a strong dawnward component. The contrast between the sunlit and dark side increases with increasing values of the $\mathit{F}_{10.7}$ index, showing that increasing solar EUV flux changes not only the magnitude but also the morphology of the equivalent current system. The results are consistent with a recent study showing that Birkeland currents indirectly determine the equivalent current in darkness and that Hall currents dominate in sunlight. This has implication for the interpretation of ground magnetic field measurements and suggests that the magnetic disturbances at conjugate points will be asymmetrical when the solar illumination is different.

Published
2016
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21. Estimation of cold plasma outflow during geomagnetic storms

Author

Haaland, S., Eriksson, A., André, M., Maes, L., Baddeley, L., Barakat, A., Chappell, R., Eccles, V., Johnsen, C., Lybekk, B., Li, K., Pedersen, A., Schunk, R., and Welling, D.

Subjects
Physics - Space Physics
Abstract

Low-energy ions of ionospheric origin constitute a significant contributor to the magnetospheric plasma population. Measuring cold ions is difficult though. Observations have to be done at sufficiently high altitudes and typically in regions of space where spacecraft attain a positive charge due to solar illumination. Cold ions are therefore shielded from the satellite particle detectors. Furthermore, spacecraft can only cover key regions of ion outflow during segments of their orbit, so additional complications arise if continuous longtime observations, such as during a geomagnetic storm, are needed. In this paper we suggest a new approach, based on a combination of synoptic observations and a novel technique to estimate the flux and total outflow during the various phases of geomagnetic storms. Our results indicate large variations in both outflow rates and transport throughout the storm. Prior to the storm main phase, outflow rates are moderate, and the cold ions are mainly emanating from moderately sized polar cap regions. Throughout the main phase of the storm, outflow rates increase and the polar cap source regions expand. Furthermore, faster transport, resulting from enhanced convection, leads to a much larger supply of cold ions to the near-Earth region during geomagnetic storms.

Published
2016
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23. Magnetopause and Boundary Layer

Author

De Keyser, J., Dunlop, M. W., Owen, C. J., Sonnerup, B. U. Ö., Haaland, S. E., Vaivads, A., Paschmann, G., Lundin, R., Rezeau, L., Paschmann, G., editor, Schwartz, S. J., editor, Escoubet, C. P., editor, and Haaland, S., editor

Published
2005
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24. Introduction

Author

Paschmann, G., Escoubet, C. P., Schwartz, S. J., Haaland, S. E., Paschmann, G., editor, Schwartz, S. J., editor, Escoubet, C. P., editor, and Haaland, S., editor

Published
2005
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27. Low-energy Ion Outflow Observed by Cluster

Author

Haaland, S., primary, André, M., additional, Eriksson, A., additional, Li, K., additional, Nilsson, H., additional, Baddeley, L., additional, Johnsen, C., additional, Maes, L., additional, Lybekk, B., additional, and Pedersen, A., additional

Published
2016
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29. Spatial evolution of magnetic reconnection diffusion region structures with distance from the X-line

Author

Øieroset, M., primary, Phan, T. D., additional, Ergun, R., additional, Ahmadi, N., additional, Genestreti, K., additional, Drake, J. F., additional, Liu, Y.-H., additional, Haggerty, C., additional, Eastwood, J. P., additional, Shay, M. A., additional, Pyakurel, P. S., additional, Haaland, S., additional, Oka, M., additional, Goodbred, M., additional, Eriksson, S., additional, Burch, J. L., additional, Torbert, R. B., additional, Khotyaintsev, Y., additional, Russell, C. T., additional, Strangeway, R. J., additional, Gershman, D. J., additional, and Giles, B. L., additional

Published
2021
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30. Turbulence Heating ObserveR: - Satellite Mission Proposal

Author

Vaivads, A, Retino, A, Soucek, J, Khotyaintsev, Yu V, Valentini, F, Escoubet, C. P, Alexandrova, O, Andre, M, Bale, S. D, Balikhin, M, Burgess, D, Camporeale, E, Caprioli, D, Chen, C. H. K, Clacey, E, Cully, C. M, De Keyser, J, Eastwood, J. P, Fazakerley, A. N, Eriksson, S, Goldstein, M. L, Graham, D. B, Haaland, S, Hoshino, M, Ji, H, Karimabadi, H, Kucharek, H, Lavraud, B, Marcucci, F, Moore, T. E, and Nakamura, R

Subjects
Space Sciences (General)
Abstract

The Universe is permeated by hot, turbulent, magnetized plasmas. Turbulent plasma is a major constituent of active galactic nuclei, supernova remnants, the intergalactic and interstellar medium, the solar corona, the solar wind and the Earths magnetosphere, just to mention a few examples. Energy dissipation of turbulent fluctuations plays a key role in plasma heating and energization, yet we still do not understand the underlying physical mechanisms involved. THOR is a mission designed to answer the questions of how turbulent plasma is heated and particles accelerated, how the dissipated energy is partitioned and how dissipation operates in different regimes of turbulence. THOR is a single-spacecraft mission with an orbit tuned to maximize data return from regions in near-Earth space magnetosheath, shock, foreshock and pristine solar wind featuring different kinds of turbulence. Here we summarize the THOR proposal submitted on 15 January 2015 to the Call for a Medium-size mission opportunity in ESAs Science Programme for a launch in 2025 (M4). THOR has been selected by European Space Agency (ESA) for the study phase.

Published
2016
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32. Curlometer Technique and Applications

Author

Dunlop, M. W., primary, Dong, X.‐C., additional, Wang, T.‐Y., additional, Eastwood, J. P., additional, Robert, P., additional, Haaland, S., additional, Yang, Y.‐Y., additional, Escoubet, P., additional, Rong, Z.‐J., additional, Shen, C., additional, Fu, H.‐S., additional, and De Keyser, J., additional

Published
2021
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33. Quantification of Cold-Ion Beams in a Magnetic Reconnection Jet

Author

Li, Yu-Xuan, primary, Li, Wen-Ya, additional, Tang, Bin-Bin, additional, Norgren, C., additional, He, Jian-Sen, additional, Wang, Chi, additional, Zong, Qiu-Gang, additional, Toledo-Redondo, S., additional, André, M., additional, Chappell, C., additional, Dargent, J., additional, Fuselier, S. A., additional, Glocer, A., additional, Graham, D. B., additional, Haaland, S., additional, Kistler, L., additional, Lavraud, B., additional, Moore, T. E., additional, Tenfjord, P., additional, Vines, S. K., additional, and Burch, J., additional

Published
2021
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34. Anomalous Reconnection Layer at Earth's Dayside Magnetopause

Author

Paschmann, G., primary, Sonnerup, B. U. Ö., additional, Phan, T., additional, Fuselier, S. A., additional, Haaland, S., additional, Denton, R. E., additional, Burch, J. L., additional, Trattner, K. J., additional, Giles, B. L., additional, Gershman, D. J., additional, Cohen, I. J., additional, and Russell, C. T., additional

Published
2021
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37. Impacts of Ionospheric Ions on Magnetic Reconnection and Earth's Magnetosphere Dynamics

Author

Toledo‐Redondo, S., primary, André, M., additional, Aunai, N., additional, Chappell, C. R., additional, Dargent, J., additional, Fuselier, S. A., additional, Glocer, A., additional, Graham, D. B., additional, Haaland, S., additional, Hesse, M., additional, Kistler, L. M., additional, Lavraud, B., additional, Li, W., additional, Moore, T. E., additional, Tenfjord, P., additional, and Vines, S. K., additional

Published
2021
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38. Results of the Electron Drift Instrument on Cluster

Author

Paschmann, G., primary, Quinn, J. M., additional, Torbert, R. B., additional, McIlwain, C. E., additional, Vaith, H., additional, Haaland, S., additional, Matsui, H., additional, Kletzing, C. A., additional, Baumjohann, W., additional, and Haerendel, G., additional

Published
2021
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39. Spatial evolution of magnetic reconnection diffusion region structures with distance from the X-line

Author

Oieroset, M., Phan, T. D., Ergun, R., Ahmadi, N., Genestreti, K., Drake, J. F., Liu, Y-H, Haggerty, C., Eastwood, J. P., Shay, M. A., Pyakurel, P. S., Haaland, S., Oka, M., Goodbred, M., Eriksson, S., Burch, J. L., Torbert, R. B., Khotyaintsev, Yuri V., Russell, C. T., Strangeway, R. J., Gershman, D. J., Giles, B. L., Oieroset, M., Phan, T. D., Ergun, R., Ahmadi, N., Genestreti, K., Drake, J. F., Liu, Y-H, Haggerty, C., Eastwood, J. P., Shay, M. A., Pyakurel, P. S., Haaland, S., Oka, M., Goodbred, M., Eriksson, S., Burch, J. L., Torbert, R. B., Khotyaintsev, Yuri V., Russell, C. T., Strangeway, R. J., Gershman, D. J., and Giles, B. L.

Abstract

We report Magnetospheric Multiscale four-spacecraft observations of a thin reconnecting current sheet with weakly asymmetric inflow conditions and a guide field of approximately twice the reconnecting magnetic field. The event was observed at the interface of interlinked magnetic field lines at the flank magnetopause when the maximum spacecraft separation was 370 km and the spacecraft covered & SIM;1.7 ion inertial lengths (d(i)) in the reconnection outflow direction. The ion-scale spacecraft separation made it possible to observe the transition from electron-only super ion-Alfvenic outflow near the electron diffusion region (EDR) to the emergence of sub-Alfvenic ion outflow in the ion diffusion region (IDR). The EDR to IDR evolution over a distance less than 2 d(i) also shows the transition from a near-linear reconnecting magnetic field reversal to a more bifurcated current sheet as well as significant decreases in the parallel electric field and dissipation. Both the ion and electron heating in this diffusion region event were similar to the previously reported heating in the far downstream exhausts. The dimensionless reconnection rate, obtained four different ways, was in the range of 0.13-0.27. This event reveals the rapid spatial evolution of the plasma and electromagnetic fields through the EDR to IDR transition region.& nbsp;(C) 2021 Author(s). All article content, except where otherwise noted, is licensed under a Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).

Published
2021
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40. Quantification of Cold-Ion Beams in a Magnetic Reconnection Jet

Author

Li, Yu-Xuan, Li, Wen-Ya, Tang, Bin-Bin, Norgren, C., He, Jian-Sen, Wang, Chi, Zong, Qiu-Gang, Toledo-Redondo, S., André, Mats, Chappell, C., Dargent, J., Fuselier, S. A., Glocer, A., Graham, Daniel B., Haaland, S., Kistler, L., Lavraud, B., Moore, T. E., Tenfjord, P., Vines, S. K., Burch, J., Li, Yu-Xuan, Li, Wen-Ya, Tang, Bin-Bin, Norgren, C., He, Jian-Sen, Wang, Chi, Zong, Qiu-Gang, Toledo-Redondo, S., André, Mats, Chappell, C., Dargent, J., Fuselier, S. A., Glocer, A., Graham, Daniel B., Haaland, S., Kistler, L., Lavraud, B., Moore, T. E., Tenfjord, P., Vines, S. K., and Burch, J.

Abstract

Cold (few eV) ions of ionospheric origin are widely observed in the lobe region of Earth's magnetotail and can enter the ion jet region after magnetic reconnection is triggered in the magnetotail. Here, we investigate a magnetotail crossing with cold ions in one tailward and two earthward ion jets observed by the Magnetospheric Multiscale (MMS) constellation of spacecraft. Cold ions co-existing with hot plasma-sheet ions form types of ion velocity distribution functions (VDFs) in the three jets. In one earthward jet, MMS observe cold-ion beams with large velocities parallel to the magnetic fields, and we perform quantitative analysis on the ion VDFs in this jet. The cold ions, together with the hot ions, are reconnection outflow ions and are a minor population in terms of number density inside this jet. The average bulk speed of the cold-ion beams is approximately 38% larger than that of the hot plasma-sheet ions. The cold-ion beams inside the explored jet are about one order of magnitude colder than the hot plasma-sheet ions. These cold-ion beams could be accelerated by the Hall electric field in the cold ion diffusion region and the shrinking magnetic field lines through the Fermi effect.

Published
2021
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41. Impacts of Ionospheric Ions on Magnetic Reconnection and Earth's Magnetosphere Dynamics

Author

Toledo-Redondo, S., André, Mats, Aunai, N., Chappell, C. R., Dargent, J., Fuselier, S. A., Glocer, A., Graham, Daniel B., Haaland, S., Hesse, M., Kistler, L. M., Lavraud, B., Li, W., Moore, T. E., Tenfjord, P., Vines, S. K., Toledo-Redondo, S., André, Mats, Aunai, N., Chappell, C. R., Dargent, J., Fuselier, S. A., Glocer, A., Graham, Daniel B., Haaland, S., Hesse, M., Kistler, L. M., Lavraud, B., Li, W., Moore, T. E., Tenfjord, P., and Vines, S. K.

Abstract

Ionospheric ions (mainly H+, He+, and O+) escape from the ionosphere and populate the Earth's magnetosphere. Their thermal energies are usually low when they first escape the ionosphere, typically a few electron volt to tens of electron volt, but they are energized in their journey through the magnetosphere. The ionospheric population is variable, and it makes significant contributions to the magnetospheric mass density in key regions where magnetic reconnection is at work. Solar wind—magnetosphere coupling occurs primarily via magnetic reconnection, a key plasma process that enables transfer of mass and energy into the near-Earth space environment. Reconnection leads to the triggering of magnetospheric storms, auroras, energetic particle precipitation and a host of other magnetospheric phenomena. Several works in the last decades have attempted to statistically quantify the amount of ionospheric plasma supplied to the magnetosphere, including the two key regions where magnetic reconnection occurs: the dayside magnetopause and the magnetotail. Recent in situ observations by the Magnetospheric Multiscale spacecraft and associated modeling have advanced our current understanding of how ionospheric ions alter the magnetic reconnection process, including its onset and efficiency. This article compiles the current understanding of the ionospheric plasma supply to the magnetosphere. It reviews both the quantification of these sources and their effects on the process of magnetic reconnection. It also provides a global description of how the ionospheric ion contribution modifies the way the solar wind couples to the Earth's magnetosphere and how these ions modify the global dynamics of the near-Earth space environment. Plain Language Summary Above the neutral atmosphere, space is filled with charged particles, which are tied to the Earth's magnetic field. The particles come from two sources, the solar wind and the Earth's upper atmosphere. Most of the solar wind particles a

Published
2021
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42. Particle energization in space plasmas : towards a multi-point, multi-scale plasma observatory

Author

Retinò, A., Khotyaintsev, Y., Le Contel, O., Marcucci, M. F., Plaschke, F., Vaivads, Andris, Angelopoulos, V., Blasi, P., Burch, J., De Keyser, J., Dunlop, M., Dai, L., Eastwood, J., Fu, H., Haaland, S., Hoshino, M., Johlander, A., Kepko, L., Kucharek, H., Lapenta, G., Lavraud, B., Malandraki, O., Matthaeus, W., McWilliams, K., Petrukovich, A., Pinçon, J. -L, Saito, Y., Sorriso-Valvo, L., Vainio, R., Wimmer-Schweingruber, R., Retinò, A., Khotyaintsev, Y., Le Contel, O., Marcucci, M. F., Plaschke, F., Vaivads, Andris, Angelopoulos, V., Blasi, P., Burch, J., De Keyser, J., Dunlop, M., Dai, L., Eastwood, J., Fu, H., Haaland, S., Hoshino, M., Johlander, A., Kepko, L., Kucharek, H., Lapenta, G., Lavraud, B., Malandraki, O., Matthaeus, W., McWilliams, K., Petrukovich, A., Pinçon, J. -L, Saito, Y., Sorriso-Valvo, L., Vainio, R., and Wimmer-Schweingruber, R.

Abstract

This White Paper outlines the importance of addressing the fundamental science theme “How are charged particles energized in space plasmas” through a future ESA mission. The White Paper presents five compelling science questions related to particle energization by shocks, reconnection, waves and turbulence, jets and their combinations. Answering these questions requires resolving scale coupling, nonlinearity, and nonstationarity, which cannot be done with existing multi-point observations. In situ measurements from a multi-point, multi-scale L-class Plasma Observatory consisting of at least seven spacecraft covering fluid, ion, and electron scales are needed. The Plasma Observatory will enable a paradigm shift in our comprehension of particle energization and space plasma physics in general, with a very important impact on solar and astrophysical plasmas. It will be the next logical step following Cluster, THEMIS, and MMS for the very large and active European space plasmas community. Being one of the cornerstone missions of the future ESA Voyage 2050 science programme, it would further strengthen the European scientific and technical leadership in this important field., QC 20220517

Published
2021
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43. EIDOSCOPE: particle acceleration at plasma boundaries

Author

Vaivads, A., Andersson, G., Bale, S. D., Cully, C. M., De Keyser, J., Fujimoto, M., Grahn, S., Haaland, S., Ji, H., Khotyaintsev, Yu. V., Lazarian, A., Lavraud, B., Mann, I. R., Nakamura, R., Nakamura, T. K. M., Narita, Y., Retinò, A., Sahraoui, F., Schekochihin, A., Schwartz, S. J., Shinohara, I., and Sorriso-Valvo, L.

Published
2012
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45. Separation and Quantification of Ionospheric Convection Sources: 2. The Dipole Tilt Angle Influence on Reverse Convection Cells During Northward IMF

Author

Reistad, J. P., Laundal, K. M., ��steward, N., Ohma, A., Thomas, E. G., Haaland, S., Oksavik, K., and Milan, S. E.

Subjects
Physics - Space Physics, Physics::Space Physics, FOS: Physical sciences, Astrophysics::Solar and Stellar Astrophysics, Space Physics (physics.space-ph), Physics::Atmospheric and Oceanic Physics, Physics::Geophysics
Abstract

This paper investigates the influence of Earth's dipole tilt angle on the reverse convection cells (sometimes referred to as lobe cells) in the Northern Hemisphere ionosphere during northward IMF, which we relate to high-latitude reconnection. Super Dual Auroral Radar Network plasma drift observations in 2010-2016 are used to quantify the ionospheric convection. A novel technique based on Spherical Elementary Convection Systems (SECS) that was presented in our companion paper (Reistad et al., 2019, https://doi.org/10.1029/2019JA026634) is used to isolate and quantify the reverse convection cells. We find that the dipole tilt angle has a linear influence on the reverse cell potential. In the Northern Hemisphere the reverse cell potential is typically two times higher in summer than in winter. This change is interpreted as the change in interplanetary magnetic field-lobe reconnection rate due to the orientation of the dipole tilt. Hence, the dipole tilt influence on reverse ionospheric convection can be a significant modification of the more known influence from v(O$_{sw}$)B(O$_{z}$). These results could be adopted by the scientific community as key input parameters for lobe reconnection coupling functions.

Published
2020

46. Response of Earth's Neutral Sheet to Reversals in the IMF B-y Component

Author

Case, N. A., Grocott, A., Haaland, S., Martin, C. J., and Nagai, Tsugunobu

Subjects
Physics, 010504 meteorology & atmospheric sciences, Component (thermodynamics), Polarity (physics), Thin layer, Flow (psychology), Flux, Astrophysics, 010502 geochemistry & geophysics, Rotation, 01 natural sciences, Geophysics, Space and Planetary Science, Orientation (geometry), Physics::Space Physics, Interplanetary magnetic field, Astrophysics::Galaxy Astrophysics, 0105 earth and related environmental sciences
Abstract

Accepted: 2018-09-27, 資料番号: SA1180156000

Published
2018

47. Cold Ion Outflow as a Source of Plasma for the Magnetosphere

Author

Haaland, S., primary, Li, K., additional, Eriksson, A., additional, André, M., additional, Engwall, E., additional, FöRster, M., additional, Johnsen, C., additional, Lybekk, B., additional, Nilsson, H., additional, ØStgaard, N., additional, Pedersen, A., additional, and Svenes, K., additional

Published
2013
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48. High‐Density Magnetospheric He + at the Dayside Magnetopause and Its Effect on Magnetic Reconnection

Author

Fuselier, S. A., primary, Haaland, S., additional, Tenfjord, P., additional, Paschmann, G., additional, Toledo‐Redondo, S., additional, Malaspina, D., additional, Kim, M. J., additional, Trattner, K. J., additional, Petrinec, S. M., additional, Giles, B. L., additional, Goldstein, J., additional, Burch, J. L., additional, and Strangeway, R. J., additional

Published
2021
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50. Comparison of the Flank Magnetopause at Near‐Earth and Lunar Distances: MMS and ARTEMIS Observations

Author

Lukin, A. S., primary, Panov, E. V., additional, Artemyev, A. V., additional, Petrukovich, A. A., additional, Haaland, S., additional, Nakamura, R., additional, Angelopoulos, V., additional, Runov, A., additional, Yushkov, E. V., additional, Avanov, L. A., additional, Giles, B. L., additional, Russell, C. T., additional, and Strangeway, R. J., additional

Published
2020
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