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296 results on '"Buchert, S."'

1. Solar radio emission as a disturbance of aeronautical radionavigation

Author

Marqué, C., Klein, K. -L., Monstein, C., Opgenoorth, H., Pulkkinen, A., Buchert, S., Krucker, S., Van Hoof, R., and Thulesen, P.

Subjects
Astrophysics - Solar and Stellar Astrophysics
Abstract

On November 4th 2015 secondary air traffic control radar was strongly disturbed in Sweden and some other European countries. The disturbances occurred when the radar antennas were pointing at the Sun. In this paper, we show that the disturbances coincided with the time of peaks of an exceptionally strong ($\sim 10^5$ Solar Flux Units) solar radio burst in a relatively narrow frequency range around 1~GHz. This indicates that this radio burst is the most probable space weather candidate for explaining the radar disturbances. The dynamic radio spectrum shows that the high flux densities are not due to synchrotron emission of energetic electrons, but to coherent emission processes, which produce a large variety of rapidly varying short bursts (such as pulsations, fiber bursts, and zebra patterns). The radio burst occurs outside the impulsive phase of the associated flare, about 30 minutes after the soft X-ray peak, and it is temporarily associated with fast evolving activity occurring in strong solar magnetic fields. While the relationship with strong magnetic fields and the coherent spectral nature of the radio burst provide hints towards the physical processes which generate such disturbances, we have so far no means to forecast them. Well-calibrated monitoring instruments of whole Sun radio fluxes covering the UHF band could at least provide a real-time identification of the origin of such disturbances, which reports in the literature show to also affect GPS signal reception., Comment: Accepted for publication in the Journal of Space Weather and Space Climate (JSWSC), 20 pages, 7 figures

Published
2018

2. Investigating the Trip of a Transformer in Sweden During the 24 April 2023 Storm.

Author

Dimmock, A. P., Lanabere, V., Johlander, A., Rosenqvist, L., Yordanova, E., Buchert, S., Molenkamp, S., and Setréus, J.

Abstract

Geomagnetically Induced Currents are unwanted currents that flow in large ground‐based conductive infrastructure and are a significant threat to bulk power grids. This susceptibility is increased at high latitudes due to the larger amplitude geomagnetic disturbances caused by the strong and dynamic auroral electrojet currents. In Sweden, there has been a record of disturbances connected to geomagnetically induced currents; the most documented was a blackout in Malmö, a city in southern Sweden, on 30 October 2003. However, on 24 April 2023, there was a transformer trip in the Bandsjö substation (near Sundsvall) around the time of enhanced space weather. In this paper, we investigate this event by studying the solar wind properties as well as geomagnetic disturbances. The study shows evidence that the transformer trip was caused by a strong geomagnetic disturbance in the morning sector. This was triggered by a high‐pressure sub‐structure within the interplanetary coronal mass ejection cloud, preceded by 2 hr of strong southward interplanetary magnetic field. Additionally, analysis of multiple ground magnetometers shows that the geomagnetic impact was highly spatially structured. Plain Language Summary: Space weather is a field of research that connects the changing conditions on the Sun and around near‐Earth space to effects on human technology and health. Occasionally, eruptions on the Sun will release large blobs of plasma known as interplanetary coronal mass ejections that travel outward into interplanetary space. When an interplanetary coronal mass ejection reaches Earth, it will interact with the Earth's near‐space environment, for example, by distorting and compressing the Earth's magnetic field. The focus of this study is a space weather phenomenon known as geomagnetically induced currents, which are unwanted currents that flow in large ground‐based conductors. Geomagnetically induced currents are caused by the changing Earth's magnetic field during the Earth's interaction with an interplanetary coronal mass ejection. Here, we study a trip of a Swedish power transformer to determine if it was caused by space weather. After our analysis, we show strong evidence that it was related to GICs, and we can also trace the effect to a clear feature inside the interplanetary coronal mass ejection. Key Points: An interplanetary coronal mass ejection cloud sub‐structure preceded by 2 hr of southward interplanetary magnetic field resulted in strong geoelectric fields in SwedenPower line voltage calculations show strong evidence that the large geoelectric fields caused a transformer to trip in SwedenThe geomagnetic disturbance was spatially structured, where the largest amplitude perturbation was recorded in Norway [ABSTRACT FROM AUTHOR]

Published
2024
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3. Swarm in situ observations of F region polar cap patches created by cusp precipitation

Author

Goodwin, L. V., Iserhienrhien, B., Miles, D. M., Patra, S., van der Meeren, C., Buchert, S. C., Burchill, J. K., Clausen, L. B. N., Knudsen, D. J., McWilliams, K. A., and Moen, J.

Subjects
Physics - Space Physics
Abstract

High-resolution in situ measurements from the three Swarm spacecraft, in a string-of-pearls configuration, provide new insights about the combined role of flow channel events and particle impact ionization in creating $\textit{F}$ region electron density structures in the northern Scandinavian dayside cusp. We present a case of polar cap patch formation where a reconnection-driven low-density relative westward flow channel is eroding the dayside solar-ionized plasma but where particle impact ionization in the cusp dominates the initial plasma structuring. In the cusp, density features are observed which are twice as dense as the solar-ionized background. These features then follow the polar cap convection and become less structured and lower in amplitude. These are the first in situ observations tracking polar cap patch evolution from creation by plasma transport and enhancement by cusp precipitation, through entrainment in the polar cap flow and relaxation into smooth patches as they approach the nightside auroral oval.

Published
2016
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4. Effect of Polar Cap Patches on the High-Latitude Upper Thermospheric Winds

Author

Cai, L., Aikio, A., Oyama, S., Ivchenko, Nickolay, Vanhamäki, H., Virtanen, I., Buchert, S., Mekuriaw, M. L., Zhang, Y., Cai, L., Aikio, A., Oyama, S., Ivchenko, Nickolay, Vanhamäki, H., Virtanen, I., Buchert, S., Mekuriaw, M. L., and Zhang, Y.

Abstract

This study focuses on the poorly known effect of polar cap patches (PCPs) on the ion-neutral coupling in the F-region. The PCPs were identified by total electron content measurements from the Global Navigation Satellite System (GNSS) and the ionospheric parameters from the Defense Meteorological Satellite Program spacecraft. The EISCAT incoherent scatter radars on Svalbard and at Tromsø, Norway observed that PCPs entered the nightside auroral oval from the polar cap and became plasma blobs. The ionospheric convection further transported the plasma blobs to the duskside. Simultaneously, long-lasting strong upper thermospheric winds were detected in the duskside auroral oval by a Fabry-Perot Interferometer (FPI) at Tromsø and in the polar cap by the Gravity Recovery and Climate Experiment satellite. Using EISCAT ion velocities and plasma parameters as well as FPI winds, the ion drag acting on neutrals and the time constant for the ion drag could be estimated. Due to the arrival of PCPs/blobs and the accompanied increase in the F-region electron densities, the ion drag is enhanced between about 220 and 500 km altitudes. At the F peak altitudes near 300 km, the median ion drag acceleration affecting neutrals more than doubled and the associated median e-folding time decreased from 4.4 to 2 hr. The strong neutral wind was found to be driven primarily by the ion drag force due to large-scale ionospheric convection. Our results provide a new insight into ionosphere-thermosphere coupling in the presence of PCPs/blobs., QC 20240814

Published
2024
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6. High-altitude signatures of ionospheric density depletions caused by field-aligned currents

Author

Karlsson, T., Brenning, N., Marghitu, O., Marklund, G., and Buchert, S.

Subjects
Physics - Space Physics, Physics - Plasma Physics
Abstract

We present Cluster measurements of large electric fields correlated with intense downward field-aligned currents, and show that the data can be reproduced by a simple model of ionospheric plasma depletion caused by the currents. This type of magnetosphere-ionosphere interaction may be important when considering the mapping between these two regions of space.

Published
2007

7. Plasma-neutral interactions in the lower thermosphere-ionosphere:the need for in situ measurements to address focused questions

Author

Sarris, T. (Theodoros), Palmroth, M. (Minna), Aikio, A. (Anita), Buchert, S. C. (Stephan Christoph), Clemmons, J. (James), Clilverd, M. (Mark), Dandouras, I. (Iannis), Doornbos, E. (Eelco), Goodwin, L. V. (Lindsay Victoria), Grandin, M. (Maxime), Heelis, R. (Roderick), Ivchenko, N. (Nickolay), Moretto-Jørgensen, T. (Therese), Kervalishvili, G. (Guram), Knudsen, D. (David), Liu, H.-L. (Han-Li), Lu, G. (Gang), Malaspina, D. M. (David M.), Marghitu, O. (Octav), Maute, A. (Astrid), Miloch, W. J. (Wojciech J.), Olsen, N. (Nils), Pfaff, R. (Robert), Stolle, C. (Claudia), Talaat, E. (Elsayed), Thayer, J. (Jeffrey), Tourgaidis, S. (Stelios), Verronen, P. T. (Pekka T.), Yamauchi, M. (Masatoshi), Sarris, T. (Theodoros), Palmroth, M. (Minna), Aikio, A. (Anita), Buchert, S. C. (Stephan Christoph), Clemmons, J. (James), Clilverd, M. (Mark), Dandouras, I. (Iannis), Doornbos, E. (Eelco), Goodwin, L. V. (Lindsay Victoria), Grandin, M. (Maxime), Heelis, R. (Roderick), Ivchenko, N. (Nickolay), Moretto-Jørgensen, T. (Therese), Kervalishvili, G. (Guram), Knudsen, D. (David), Liu, H.-L. (Han-Li), Lu, G. (Gang), Malaspina, D. M. (David M.), Marghitu, O. (Octav), Maute, A. (Astrid), Miloch, W. J. (Wojciech J.), Olsen, N. (Nils), Pfaff, R. (Robert), Stolle, C. (Claudia), Talaat, E. (Elsayed), Thayer, J. (Jeffrey), Tourgaidis, S. (Stelios), Verronen, P. T. (Pekka T.), and Yamauchi, M. (Masatoshi)

Abstract

The lower thermosphere-ionosphere (LTI) is a key transition region between Earth’s atmosphere and space. Interactions between ions and neutrals maximize within the LTI and in particular at altitudes from 100 to 200 km, which is the least visited region of the near-Earth environment. The lack of in situ co-temporal and co-spatial measurements of all relevant parameters and their elusiveness to most remote-sensing methods means that the complex interactions between its neutral and charged constituents remain poorly characterized to this date. This lack of measurements, together with the ambiguity in the quantification of key processes in the 100–200 km altitude range affect current modeling efforts to expand atmospheric models upward to include the LTI and limit current space weather prediction capabilities. We present focused questions in the LTI that are related to the complex interactions between its neutral and charged constituents. These questions concern core physical processes that govern the energetics, dynamics, and chemistry of the LTI and need to be addressed as fundamental and long-standing questions in this critically unexplored boundary region. We also outline the range of in situ measurements that are needed to unambiguously quantify key LTI processes within this region, and present elements of an in situ concept based on past proposed mission concepts.

Published
2023

8. Joule Heating and the Atmospheric Dynamo

Author

Buchert, S., Tourgaidis, S., and Sarris, T.

Abstract

Joule heating (JH) in the thermosphere is known to result from the couplingbetween the ionosphere and magnetosphere at high latitudes. A so far relativelyneglected contribution to JH comes from atmospheric motions which, according to magnetic observations, cause electric currents and so constitute a dynamo in a dissipative medium. We present a general theoretical description of the coupling between atmosphere and the ionosphere with a dynamo equationwhere the well-known Pedersen and Hall conductivities appear. The derivation is based on a paper by Parker (1996). A dynamo effect occurs when ∇x(uxB)≠0, where u is the neutral wind and B the magnetic field. The conductivity parallel to B is orders of magnitudes higher than the Pedersen and Hall conductivities. Thus, if uxB is varying along magnetic field lines, then dissipative dynamo currents develop. For example, at gravity waves generally uxB varies along magnetic field lines, and so dynamo effects are produced when they propagate into the dynamo regions of the lower thermosphere.We estimate that the tidal Sq dynamo globally dissipates roughly a power of 2 GW quasi-permanently. But also the electrodynamic dissipation by medium and small scale gravity waves propagating from the mesosphere into the lower thermosphere could be a significant source of heat. Unlike the current systems coupling the magnetosphere and ionosphere which are observed by satellites like Swarm, the currents of a gravity wave dynamo are confined to the lower thermosphere and can only be observed with a very low orbiting satellite or sounding rockets., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published
2023
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11. The Cluster Magnetic Field Investigation

Author

The Cluster Magnetometer Team, Balogh, A., Dunlop, M. W., Cowley, S. W. H., Southwood, D. J., Thomlinson, J. G., Glassmeier, K. H., Musmann, G., Lühr, H., Buchert, S., Acuña, M. H., Fairfield, D. H., Slavin, J. A., Riedler, W., Schwingenschuh, K., Kivelson, M. G., Escoubet, C. P., editor, Russell, C. T., editor, and Schmidt, R., editor

Published
1997
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12. Lower-thermosphere–ionosphere (LTI) quantities:current status of measuring techniques and models

Author

Palmroth, M. (Minna), Grandin, M. (Maxime), Sarris, T. (Theodoros), Doornbos, E. (Eelco), Tourgaidis, S. (Stelios), Aikio, A. (Anita), Buchert, S. (Stephan), Clilverd, M. A. (Mark A.), Dandouras, I. (Iannis), Heelis, R. (Roderick), Hoffmann, A. (Alex), Ivchenko, N. (Nickolay), Kervalishvili, G. (Guram), Knudsen, D. J. (David J.), Kotova, A. (Anna), Liu, H.-L. (Han-Li), Malaspina, D. M. (David M.), March, G. (Gunther), Marchaudon, A. (Aurelie), Marghitu, O. (Octav), Matsuo, T. (Tomoko), Miloch, W. J. (Wojciech J.), Moretto-Jorgensen, T. (Therese), Mpaloukidis, D. (Dimitris), Olsen, N. (Nils), Papadakis, K. (Konstantinos), Pfaff, R. (Robert), Pirnaris, P. (Panagiotis), Siemes, C. (Christian), Stolle, C. (Claudia), Suni, J. (Jonas), van den IJssel, J. (Jose), Verronen, P. T. (Pekka T.), Visser, P. (Pieter), and Yamauchi, M. (Masatoshi)

Abstract

The lower-thermosphere–ionosphere (LTI) system consists of the upper atmosphere and the lower part of the ionosphere and as such comprises a complex system coupled to both the atmosphere below and space above. The atmospheric part of the LTI is dominated by laws of continuum fluid dynamics and chemistry, while the ionosphere is a plasma system controlled by electromagnetic forces driven by the magnetosphere, the solar wind, as well as the wind dynamo. The LTI is hence a domain controlled by many different physical processes. However, systematic in situ measurements within this region are severely lacking, although the LTI is located only 80 to 200 km above the surface of our planet. This paper reviews the current state of the art in measuring the LTI, either in situ or by several different remote-sensing methods. We begin by outlining the open questions within the LTI requiring high-quality in situ measurements, before reviewing directly observable parameters and their most important derivatives. The motivation for this review has arisen from the recent retention of the Daedalus mission as one among three competing mission candidates within the European Space Agency (ESA) Earth Explorer 10 Programme. However, this paper intends to cover the LTI parameters such that it can be used as a background scientific reference for any mission targeting in situ observations of the LTI.

Published
2021

13. Lower-thermosphere-ionosphere (LTI) quantities: current status of measuring techniques and models

Author

Palmroth, M., Grandin, M., Sarris, T., Doornbos, E., Tourgaidis, S., Aikio, A., Buchert, S., Clilverd, M.A., Dandouras, I., Heelis, R., Hoffmann, A., Ivchenko, N., Kervalishvili, G., Knudsen, D.J., Kotova, A., Liu, H-L., Malaspina, D.M., March, G., Marchaudon, A., Marghitu, O., Matsuo, T., Miloch, W.J., Moretto-Jørgensen, T., Mpaloukidis, D., Olsen, N., Papadakis, K., Pfaff, R., Pirnaris, P., Siemes, C., Stolle, C., Suni, J., van den IJssel, J., Verronen, P.T., Visser, P., Yamauchi, M., Palmroth, M., Grandin, M., Sarris, T., Doornbos, E., Tourgaidis, S., Aikio, A., Buchert, S., Clilverd, M.A., Dandouras, I., Heelis, R., Hoffmann, A., Ivchenko, N., Kervalishvili, G., Knudsen, D.J., Kotova, A., Liu, H-L., Malaspina, D.M., March, G., Marchaudon, A., Marghitu, O., Matsuo, T., Miloch, W.J., Moretto-Jørgensen, T., Mpaloukidis, D., Olsen, N., Papadakis, K., Pfaff, R., Pirnaris, P., Siemes, C., Stolle, C., Suni, J., van den IJssel, J., Verronen, P.T., Visser, P., and Yamauchi, M.

Abstract

The lower-thermosphere–ionosphere (LTI) system consists of the upper atmosphere and the lower part of the ionosphere and as such comprises a complex system coupled to both the atmosphere below and space above. The atmospheric part of the LTI is dominated by laws of continuum fluid dynamics and chemistry, while the ionosphere is a plasma system controlled by electromagnetic forces driven by the magnetosphere, the solar wind, as well as the wind dynamo. The LTI is hence a domain controlled by many different physical processes. However, systematic in situ measurements within this region are severely lacking, although the LTI is located only 80 to 200 km above the surface of our planet. This paper reviews the current state of the art in measuring the LTI, either in situ or by several different remote-sensing methods. We begin by outlining the open questions within the LTI requiring high-quality in situ measurements, before reviewing directly observable parameters and their most important derivatives. The motivation for this review has arisen from the recent retention of the Daedalus mission as one among three competing mission candidates within the European Space Agency (ESA) Earth Explorer 10 Programme. However, this paper intends to cover the LTI parameters such that it can be used as a background scientific reference for any mission targeting in situ observations of the LTI.

Published
2021

14. Ionospheric Response at Conjugate Locations During the 7–8 September 2017 Geomagnetic Storm Over the Europe-African Longitude Sector

Author

Habarulema, J.B., Katamzi-Joseph, Z.T., Burešová, D., Nndanganeni, R., Matamba, T., Tshisaphungo, M., Buchert, S., Kosch, M., Lotz, S., Cilliers, P., Mahrous, A., Habarulema, J.B., Katamzi-Joseph, Z.T., Burešová, D., Nndanganeni, R., Matamba, T., Tshisaphungo, M., Buchert, S., Kosch, M., Lotz, S., Cilliers, P., and Mahrous, A.

Abstract

This paper focuses on unique aspects of the ionospheric response at conjugate locations over Europe and South Africa during the 7–8 September 2017 geomagnetic storm including the role of the bottomside and topside ionosphere and plasmasphere in influencing electron density changes. Analysis of total electron content (TEC) on 7 September 2017 shows that for a pair of geomagnetically conjugate locations, positive storm effect was observed reaching about 65% when benchmarked on the monthly median TEC variability in the Northern Hemisphere, while the Southern Hemisphere remained within the quiet time variability threshold of ±40%. Over the investigated locations, the Southern Hemisphere midlatitudes showed positive TEC deviations that were in most cases twice the comparative response level in the Northern Hemisphere on the 8 September 2017. During the storm main phase on 8 September 2017, we have obtained an interesting result of ionosonde maximum electron density of the F2 layer and TEC derived from Global Navigation Satellite System (GNSS) observations showing different ionospheric responses over the same midlatitude location in the Northern Hemisphere. In situ electron density measurements from SWARM satellite aided by bottomside ionosonde-derived TEC up to the maximum height of the F2 layer (hmF2) revealed that the bottomside and topside ionosphere as well as plasmasphere electron content contributions to overall GNSS-derived TEC were different in both hemispheres especially for 8 September 2017 during the storm main phase. The differences in hemispheric response at conjugate locations and on a regional scale have been explained in terms of seasonal influence on the background electron density coupled with the presence of large-scale traveling ionospheric disturbances and low-latitude-associated processes. The major highlight of this study is the simultaneous confirmation of most of the previously observed features and their underlying physical mechanisms during geo

Published
2020

15. Daedalus:a low-flying spacecraft for in situ exploration of the lower thermosphere–ionosphere

Author

Sarris, T. E. (Theodoros E.), Talaat, E. R. (Elsayed R.), Palmroth, M. (Minna), Dandouras, I. (Iannis), Armandillo, E. (Errico), Kervalishvili, G. (Guram), Buchert, S. (Stephan), Tourgaidis, S. (Stylianos), Malaspina, D. M. (David M.), Jaynes, A. N. (Allison N.), Paschalidis, N. (Nikolaos), Sample, J. (John), Halekas, J. (Jasper), Doornbos, E. (Eelco), Lappas, V. (Vaios), Jørgensen, T. M. (Therese Moretto), Stolle, C. (Claudia), Clilverd, M. (Mark), Wu, Q. (Qian), Sandberg, I. (Ingmar), Pirnaris, P. (Panagiotis), Aikio, A. (Anita), Sarris, T. E. (Theodoros E.), Talaat, E. R. (Elsayed R.), Palmroth, M. (Minna), Dandouras, I. (Iannis), Armandillo, E. (Errico), Kervalishvili, G. (Guram), Buchert, S. (Stephan), Tourgaidis, S. (Stylianos), Malaspina, D. M. (David M.), Jaynes, A. N. (Allison N.), Paschalidis, N. (Nikolaos), Sample, J. (John), Halekas, J. (Jasper), Doornbos, E. (Eelco), Lappas, V. (Vaios), Jørgensen, T. M. (Therese Moretto), Stolle, C. (Claudia), Clilverd, M. (Mark), Wu, Q. (Qian), Sandberg, I. (Ingmar), Pirnaris, P. (Panagiotis), and Aikio, A. (Anita)

Abstract

The Daedalus mission has been proposed to the European Space Agency (ESA) in response to the call for ideas for the Earth Observation program’s 10th Earth Explorer. It was selected in 2018 as one of three candidates for a phase-0 feasibility study. The goal of the mission is to quantify the key electrodynamic processes that determine the structure and composition of the upper atmosphere, the gateway between the Earth’s atmosphere and space. An innovative preliminary mission design allows Daedalus to access electrodynamics processes down to altitudes of 150 km and below. Daedalus will perform in situ measurements of plasma density and temperature, ion drift, neutral density and wind, ion and neutral composition, electric and magnetic fields, and precipitating particles. These measurements will unambiguously quantify the amount of energy deposited in the upper atmosphere during active and quiet geomagnetic times via Joule heating and energetic particle precipitation, estimates of which currently vary by orders of magnitude between models and observation methods. An innovation of the Daedalus preliminary mission concept is that it includes the release of subsatellites at low altitudes: combined with the main spacecraft, these subsatellites will provide multipoint measurements throughout the lower thermosphere–ionosphere (LTI) region, down to altitudes below 120 km, in the heart of the most under-explored region in the Earth’s atmosphere. This paper describes Daedalus as originally proposed to the ESA.

Published
2020

22. Temporal evolution of the electric field accelerating electrons away from the auroral ionosphere

Author

Marklund, G. T., Ivchenko, N., Karlsson, T., Fazakerley, A., Dunlop, M., Lindqvist, P.-A., Buchert, S., Owen, C., Taylor, M., Vaivalds, A., Carter, P., Andre, M., and Balogh, A.

Subjects
Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): G. T. Marklund (corresponding author) [1]; N. Ivchenko [1]; T. Karlsson [1]; A. Fazakerley [2]; M. Dunlop [3]; P.-A. Lindqvist [1]; S. Buchert [4]; C. Owen [2]; M. Taylor [...]

Published
2001
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25. THE CLUSTER MAGNETIC FIELD INVESTIGATION

Author

Balogh, A., Dunlop, M. W., Cowley, S. W. H., Southwood, D. J., Thomlinson, J. G., Glassmeier, K. H., Musmann, G., LÜHR, H., Buchert, S., AcuÑA, M. H., Fairfield, D. H., Slavin, J. A., Riedler, W., Schwingenschuh, K., and Kivelson, M. G.

Published
1997
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26. First results from the Daedalus Mission Phase-0 Study

Author

Sarris, T., Aikio, A., Buchert, S., Clilverd, M., Dandouras, I., Doornbos, E., Heelis, R., Ivchenko, N., Jørgensene, T., Kervalishvili, G., Knudsen, D., Malaspina, D., Marchaudon, A., Marghitu, O., Matsuo, T., Olsen, W., Palmroth, M., Pfaff, R., Stolle, C., Talaat, E., Verronen, P., and Visser, P.

Published
2019

27. Swarm satellite and EISCAT radar observations of a plasma flow channel in the auroral oval near magnetic midnight

Author

Aikio, A. T. (A. T.), Vanhamäki, H. (H.), Workayehu, A. B. (A. B.), Virtanen, I. I. (I. I.), Kauristie, K. (K.), Juusola, L. (L.), Buchert, S. (S.), and Knudsen, D. (D.)

Subjects
auroral oval, ionospheric currents, ionospheric electric field, Swarm satellite, plasma flow, EISCAT radar
Abstract

We present Swarm satellite and EISCAT radar observations of electrodynamical parameters in the midnight sector at high latitudes. The most striking feature is a plasma flow channel located equatorward of the polar cap boundary within the dawn convection cell. The flow channel is 1.5° wide in latitude and contains southward electric field of 150 mV/m, corresponding to eastward plasma velocities of 3,300 m/s in the F‐region ionosphere. The theoretically computed ion temperature enhancement produced by the observed ion velocity is in accordance with the measured one by the EISCAT radar. The total width of the auroral oval is about 10° in latitude. While the poleward part is electric field dominant with low conductivity and the flow channel, the equatorward part is conductivity dominant with at least five auroral arcs. The main part of the westward electrojet flows in the conductivity dominant part, but it extends to the electric field dominant part. According to Kamide and Kokubun (1996), the whole midnight sector westward electrojet is expected to be conductivity dominant, so the studied event challenges the traditional view. The flow channel is observed after substorm onset. We suggest that the observed flow channel, which is associated with a 13‐kV horizontal potential difference, accommodates increased nightside plasma flows during the substorm expansion phase as a result of reconnection in the near‐Earth magnetotail.

Published
2018

35. Estimating along-track plasma drift speed from electron density measurements by the three Swarm satellites

Author

Electrical and Computer Engineering, Park, J., Luehr, H., Stolle, Claudia, Malhotra, G., Baker, Joseph B. H., Buchert, S., Gill, R., Electrical and Computer Engineering, Park, J., Luehr, H., Stolle, Claudia, Malhotra, G., Baker, Joseph B. H., Buchert, S., and Gill, R.

Abstract

Plasma convection in the high-latitude ionosphere provides important information about magnetosphere-ionosphere-thermosphere coupling. In this study we estimate the along-track component of plasma convection within and around the polar cap, using electron density profiles measured by the three Swarm satellites. The velocity values estimated from the two different satellite pairs agree with each other. In both hemispheres the estimated velocity is generally anti-sunward, especially for higher speeds. The obtained velocity is in qualitative agreement with Super Dual Auroral Radar Network data. Our method can supplement currently available instruments for ionospheric plasma velocity measurements, especially in cases where these traditional instruments suffer from their inherent limitations. Also, the method can be generalized to other satellite constellations carrying electron density probes.

Published
2015

36. The role of the inner tail to midtail plasma sheet in channeling solar wind power to the ionosphere

Author

Hamrin, Maria, Marghitu, O, Norqvist, Patrik, Buchert, S, André, M, Klecker, B, Kistler, LM, and Dandouras, I

Subjects
energy conversion, magnetosphere-ionosphere interactions, solar wind, Astronomi, astrofysik och kosmologi, Physics::Space Physics, bursty bulk flows, Astronomy, Astrophysics and Cosmology, IMF, plasma sheet
Abstract

In this article we use Cluster power density (E . J) data from 2001, 2002, and 2004 to investigate energy conversion and transfer in the plasma sheet. We show that a southward IMF B-z is favorable for plasma sheet energy conversion, and that there is an increased particle and Poynting flux toward the Earth at times when Cluster observes an enhanced energy conversion in the plasma sheet. Conversion from electromagnetic to kinetic energy is increasingly dominant farther down-tail, while the generation of electromagnetic power from kinetic energy becomes important toward the Earth with a maximum at roughly 10 R-E. By linking observations of the key quantity E . J to observations of the solar wind input and earthward energy flux, our results demonstrate the role of the inner tail to midtail plasma sheet as a mediator between the solar wind energy input into the magnetosphere and the auroral dissipation in the ionosphere.

Published
2012

37. Detection of currents and associated electric fields in Titan's ionosphere from Cassini data

Author

Agren, K., Andrews, David J., Buchert, S. C., Coates, A. J., Cowley, S. W. H., Dougherty, M. K., Edberg, Niklas JT, Garnier, P., Lewis, G. R., Modolo, Ronan, Opgenoorth, H., Provan, G., Rosenqvist, L., Talboys, D. L., Wahlund, J.-E., Wellbrock, A., Swedish Institute of Space Physics [Uppsala] (IRF), Department of Physics and Astronomy [Leicester], University of Leicester, Mullard Space Science Laboratory (MSSL), University College of London [London] (UCL), Space and Atmospheric Physics Group [London], Blackett Laboratory, Imperial College London-Imperial College London, Centre d'étude spatiale des rayonnements (CESR), Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS), HELIOS - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Swedish Defense Research Agency (FOI), Observatoire Midi-Pyrénées (OMP), Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Météo France-Centre National d'Études Spatiales [Toulouse] (CNES)-Université Fédérale Toulouse Midi-Pyrénées-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées, and Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)

Subjects
Electric fields, Titan ionospheric physics, Currents, [SDU.STU.GP]Sciences of the Universe [physics]/Earth Sciences/Geophysics [physics.geo-ph], Saturn-Titan interaction, Cassini, [PHYS.PHYS.PHYS-SPACE-PH]Physics [physics]/Physics [physics]/Space Physics [physics.space-ph]
Abstract

International audience; We present observations from three Cassini flybys of Titan using data from the radio and plasma wave science, magnetometer and plasma spectrometer instruments. We combine magnetic field and cold plasma measurements with calculated conductivities and conclude that there are currents of the order of 10 to 100 nA m−2 flowing in the ionosphere of Titan. The currents below the exobase (∼1400 km) are principally field parallel and Hall in nature, while the Pedersen current is negligible in comparison. Associated with the currents are perpendicular electric fields ranging from 0.5 to 3 μV m−1.

Published
2011
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43. Evidence for the braking of flow bursts as they propagate toward the Earth

Author

Hamrin, M., Pitkänen, T., Norqvist, P., Karlsson, Tomas, Nilsson, H., André, M., Buchert, S., Vaivads, Andris, Marghitu, O., Klecker, B., Kistler, L. M., Dandouras, I., Hamrin, M., Pitkänen, T., Norqvist, P., Karlsson, Tomas, Nilsson, H., André, M., Buchert, S., Vaivads, Andris, Marghitu, O., Klecker, B., Kistler, L. M., and Dandouras, I.

Abstract

In this article we use energy conversion arguments to investigate the possible braking of flow bursts as they propagate toward the Earth. By using EJ data (E and J are the electric field and the current density) observed by Cluster in the magnetotail plasma sheet, we find indications of a plasma deceleration in the region -20 R-E < X < - 15 R-E. Our results suggest a braking mechanism where compressed magnetic flux tubes in so-called dipolarization fronts (DFs) can decelerate incoming flow bursts. Our results also show that energy conversion arguments can be used for studying flow braking and that the position of the flow velocity peak with respect to the DF can be used as a single-spacecraft proxy when determining energy conversion properties. Such a single-spacecraft proxy is invaluable whenever multispacecraft data are not available. In a superposed epoch study, we find that a flow burst with the velocity peak behind the DF is likely to decelerate and transfer energy from the particles to the fields. For flow bursts with the peak flow at or ahead of the DF we see no indications of braking, but instead we find an energy transfer from the fields to the particles. From our results we obtain an estimate of the magnitude of the deceleration of the flow bursts, and we find that it is consistent with previous investigations., QC 20150130

Published
2014
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45. Extreme solar-terrestrial events of October 2003: High-latitude and Cluster observations of the large geomagnetic disturbances on 30 October

Author

Rosenqvist, L., Opgenoorth, H., Buchert, S., Mccrea, I., Amm, O., Lathuillere, Chantal, Swedish Institute of Space Physics [Uppsala] (IRF), Research and Scientific Support Department, ESTEC (RSSD), European Space Research and Technology Centre (ESTEC), European Space Agency (ESA)-European Space Agency (ESA), STFC Rutherford Appleton Laboratory (RAL), Science and Technology Facilities Council (STFC), Finnish Meteorological Institute (FMI), Laboratoire de Planétologie de Grenoble (LPG), and Université Joseph Fourier - Grenoble 1 (UJF)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects
DYNAMICS, MODEL, TAIL, WIND CONTROL, ONSETS, EARTHS MAGNETOSPHERE, INTERPLANETARY MAGNETIC-FIELD, [SDU]Sciences of the Universe [physics], CLOUDS, SUBSTORMS, STORMS
Abstract

International audience; The extremely large solar eruption on 28 October 2003 caused an intense geomagnetic storm at Earth. A second solar eruption on 29 October resulted in a reintensification of the storm about a day later. Similarities and differences between these two events in terms of solar eruption, solar wind driver, and their resulting effect on the near-Earth environment are investigated and put into context of previous works on storm geoeffectivness. Within the second storm some of the strongest substorms in the history of magnetic recordings occurred in northern Scandinavia. The aim of this study is to investigate the cause and resulting effects of these extreme geomagnetic disturbances on the ionosphere and upper atmosphere, focusing on the northern Scandinavian sector where these disturbances reached extremely high values. During this time period, well after the initial arrival of the Interplanetary Coronal Mass Ejection (ICME), the Cluster spacecraft were located at the flank of the magnetospheric tail. The satellites were passed several times by an inward and consecutively outward moving magnetopause in close relation to the substorm intensifications in northern Scandinavia. We propose that the evolution of these magnetospheric substorm intensifications are influenced by the changing dynamics of the solar wind in the form of increased pressure occurring after a prolonged period of southward Interplanetary Magnetic Field (IMF) and thus excessive energy loading into the magnetosphere prior to the onset of the intensifications. We present evidence of external pressure pulse triggering and possibly also quenching of these substorm onsets and recoveries. In addition, EISCAT data have been used to investigate the detailed local behavior of the ionospheric plasma, giving rise to such extreme disturbances. We found that in this case, extreme combinations of enhanced conductivity and intense electric field resulted in very high current intensities (westward electrojet ∼7.4 MA) and very fast onset of such currents. The inline equation associated geomagnetically induced currents caused power failures in southern Sweden.

Published
2005
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46. A statistical study of intense electric fields at 4?7 RE geocentric distance using Cluster

Author

Johansson, T., Karlsson, T., Marklund, G., Figueiredo, S., Lindqvist, P.-A., Buchert, S., and EGU, Publication

Subjects
[SDU.OCEAN] Sciences of the Universe [physics]/Ocean, Atmosphere, Physics::Space Physics, [SDU.STU] Sciences of the Universe [physics]/Earth Sciences
Abstract

Intense high-latitude electric fields (>150 mV/m mapped to ionospheric altitude) at 4?7 RE geocentric distance have been investigated in a statistical study, using data from the Cluster satellites. The orbit of the Cluster satellites limits the data collection at these altitudes to high latitudes, including the poleward part of the auroral oval. The occurrence and distribution of the selected events have been used to characterize the intense electric fields and to investigate their dependance on parameters such as MLT, CGLat, altitude, and also Kp. Peaks in the local time distribution are found in the evening to morning sectors but also in the noon sector, corresponding to cusp events. The electric field intensities decrease with increasing latitude in the region investigated (above 60 CGLat). A dependence on geomagnetic activity is indicated since the probability of finding an event increases up to Kp=5?6. The scales sizes are in the range up to 10 km (mapped to ionospheric altitude) with a maximum around 4?5km, consistent with earlier findings at lower altitudes and Cluster event studies. The magnitudes of the electric fields are inversely proportional to the scale sizes. The type of electric field structure (convergent or divergent) is consistent with the FAC direction for a subset of events with electric field intensities in the range 500?1000 mV/m and with clear bipolar signatures. The FAC directions are also consistent with the Region 1 and NBZ current systems, the latter of which prevail only during northward IMF conditions. For scale sizes less than 2 km the majority of the events were divergent electric field structures. Both converging and diverging electric fields were found throughout the investigated altitude range (4?7 RE geocentric distance). Keywords. Magnetospheric physics (Electric fields; Auroral phenomena; Magnetosphere-ionosphere interactions)

Published
2005

47. Wave activity associated with thin current sheets at the magnetopause: observations by Cluster

Author

Khotyaintsev, Y., Vaivads, A., André, M., Pickett, J., Canu, P., Attié, D., Décréau, Pierrette, Buchert, S., Cardon, Catherine, Swedish Institute of Space Physics [Uppsala] (IRF), Department of Physics and Astronomy [Iowa City], University of Iowa [Iowa City], Centre d'étude des environnements terrestre et planétaires (CETP), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Laboratoire de physique et chimie de l'environnement (LPCE), and Université d'Orléans (UO)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects
[PHYS.PHYS.PHYS-AO-PH]Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph], Physics::Plasma Physics, Physics::Space Physics, [PHYS.PHYS.PHYS-AO-PH] Physics [physics]/Physics [physics]/Atmospheric and Oceanic Physics [physics.ao-ph]
Abstract

We present observations of wave activity associated with thin current sheets at the magnetopause, with main emphasis on two frequency ranges: lower hybrid/whistler and Langmuir/upper hybrid. We use multipoint measurements by the Cluster spacecraft to identify spatial properties of the waves. Most of the wave activity is concentrated on the edges of the current sheets. Langmuir/upper hybrid waves are usually observed in association with parallel currents and are generated by the electron beams carrying these currents. We also find that the appearance of lower hybrid and whistler waves depends on the value of plasma beta outside the current sheet, with no lower hybrid waves observed for high values of beta (∼ 10). We discuss mechanisms for generation of these waves, and possible relation of the observed phenomena to reconnection at the magnetopause.

Published
2004

50. The evolution of flux pileup regions in the plasma sheet : Cluster observations

Author

Hamrin, M., Norqvist, P., Karlsson, Tomas, Nilsson, H., Fu, H. S., Buchert, S., André, M., Marghitu, O., Pitkänen, T., Klecker, B., Kistler, L. M., Dandouras, I., Hamrin, M., Norqvist, P., Karlsson, Tomas, Nilsson, H., Fu, H. S., Buchert, S., André, M., Marghitu, O., Pitkänen, T., Klecker, B., Kistler, L. M., and Dandouras, I.

Abstract

Bursty bulk flows (BBFs) play an important role for the mass, energy, and magnetic flux transport in the plasma sheet, and the flow pattern in and around a BBF has important consequences for the localized energy conversion between the electromagnetic and plasma mechanical energy forms. The plasma flow signature in and around BBFs is often rather complicated. Return flows and plasma vortices are expected to exist at the flanks of the main flow channel, especially near the inner plasma sheet boundary, but also farther down-tail. A dipolarization front (DF) is often observed at the leading edge of a BBF, and a flux pileup region (FPR) behind the DF. Here we present Cluster data of three FPRs associated with vortex flows observed in the midtail plasma sheet on 15 August 2001. According to the principles of Fu et al. (2011, 2012c), two of the FPRs are considered to be in an early stage of evolution (growing FPRs). The third FPR is in a later stage of evolution (decaying FPR). For the first time, the detailed energy conversion properties during various stages of the FPR evolution have been measured. We show that the later stage FPR has a more complex vortex pattern than the two earlier stage FPRs. The two early stage FPR correspond to generators, EJ<0, while the later stage FPR only shows weak generator characteristics and is instead dominated by load signatures at the DF, EJ>0. Moreover, to our knowledge, this is one of the first times BBF-related plasma vortices have been observed to propagate over the spacecraft in the midtail plasma sheet at geocentric distances of about 18R(E). Our observations are compared to recent simulation results and previous observations., QC 20150624

Published
2013
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