Your search keyword '"Glassmeier, K. -H"' showing total 24 results

1. MASCOT—A Mobile Lander On-board the Hayabusa2 Spacecraft—Operations on Ryugu

Author

Krause, Christian, Auster, H.U., Bibring, J.-P., Biele, Jens, Cenac-Morthe, Céline, Cordero, Federico, Cozzoni, Barbara, Dudal, Clement, Embacher, Daniel, Fantinati, Cinizia, Fischer, Hans-Herbert, Glassmeier, K. H., Granena, David, Grott, Matthias, Grundmann, Jan Thimo, Hamm, V., Hercik, D., Ho, Tra-Mi, Jaumann, Ralf, Kayal, Kagan, Knollenberg, Jörg, Küchemann, Oliver, Lange, Caroline, Lorda, Laurence, Maibaum, Michael, May, Daniel, Mimasu, Yuya, Moussi-Souffys, Aurélie, Okada, T., Reill, Josef, Saiki, Takanao, Sasaki, Kaname, Schlotterer, Markus, Schmitz, Nicole, Toth, Norbert, Tsuda, Yuichi, Ulamec, Stephan, Yoshimitsu, Tetsuo, Watanabe, S., and Wolff, Friederike

Subjects

Landing, Surface, MASCOT, Asteroid, Ryugu, Hayabusa2

Published

2022

2. BepiColombo - Mission Overview and Science Goals

Author

Benkhoff, Johannes, Murakami, Go, Baumjohann, W., Besse, S., Bunce, E.J., Casale, Mauro, Cremonese, G., Glassmeier, K. H., Hayakawa, H., Heyner, Daniel, Hiesinger, H., Huovelin, Juhani, Hussmann, H., Iafolla, V., Iess, Luciano, Kasaba, Yasumasa, Kobayashi, Masanori, Milillo, Anna, Mitrofanov, Igor G., Montagnon, Elsa, Novara, M., Orsini, Stefano, Quemerais, Eric, Reininghaus, U., Saito, Yoshifumi, Santoli, Francesco, Stramaccioni, D., Sutherland, O., Thomas, N., Yoshikawa, I., Zender, Joe, Department of Physics, European Space Research and Technology Centre (ESTEC), European Space Agency (ESA), Japan Aerospace Exploration Agency [Sagamihara] (JAXA), Space Research Institute of Austrian Academy of Sciences (IWF), Austrian Academy of Sciences (OeAW), European Space Astronomy Centre (ESAC), School of Physics and Astronomy [Leicester], University of Leicester, INAF - Osservatorio Astronomico di Padova (OAPD), Istituto Nazionale di Astrofisica (INAF), Institut für Geophysik und Extraterrestrische Physik [Braunschweig] (IGEP), Technische Universität Braunschweig = Technical University of Braunschweig [Braunschweig], Institute of Space and Astronautical Science (ISAS), Institut für Planetologie [Münster], Westfälische Wilhelms-Universität Münster (WWU), Department of Physics [Helsinki], Falculty of Science [Helsinki], University of Helsinki-University of Helsinki, DLR Institut für Planetenforschung, Deutsches Zentrum für Luft- und Raumfahrt [Berlin] (DLR), Istituto di Astrofisica e Planetologia Spaziali - INAF (IAPS), Dipartimento di Ingegneria Meccanica e Aerospaziale [Roma La Sapienza] (DIMA), Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome], Planetary Plasma and Atmospheric Research Center [Sendai] (PPARC), Tohoku University [Sendai], Planetary Exploration Research Center [Chiba] (PERC), Chiba Institute of Technology (CIT), Space Research Institute of the Russian Academy of Sciences (IKI), Russian Academy of Sciences [Moscow] (RAS), European Space Operations Center (ESOC), HELIOS - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), 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), Physikalisches Institut [Bern], Universität Bern [Bern], Department of Complexity Science and Engineering [Tokyo], and The University of Tokyo (UTokyo)

Subjects

SURFACE, 010504 meteorology & atmospheric sciences, BepiColombo, Scientific Space Mission, Missions, 114 Physical sciences, 01 natural sciences, MAGNETOSPHERE, Planetary and Magnetospheric Science, 0103 physical sciences, MESSENGER OBSERVATIONS, SPECTROMETER, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, MERCURY ORBITER MISSION, Mercury exploration, 520 Astronomy, Science Goals, Astrophysics::Instrumentation and Methods for Astrophysics, Astronomy and Astrophysics, Mercury, 620 Engineering, CORNERSTONE MISSION, Surface and Interior, GAMMA-RAY, [SDU]Sciences of the Universe [physics], POLAR DEPOSITS, Space and Planetary Science, Fundamental Physics, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, VENUS, GENERATION

Abstract

BepiColombo is a joint mission between the European Space Agency, ESA, and the Japanese Aerospace Exploration Agency, JAXA, to perform a comprehensive exploration of Mercury. Launched on $20^{\mathrm{th}}$ 20 th October 2018 from the European spaceport in Kourou, French Guiana, the spacecraft is now en route to Mercury.Two orbiters have been sent to Mercury and will be put into dedicated, polar orbits around the planet to study the planet and its environment. One orbiter, Mio, is provided by JAXA, and one orbiter, MPO, is provided by ESA. The scientific payload of both spacecraft will provide detailed information necessary to understand the origin and evolution of the planet itself and its surrounding environment. Mercury is the planet closest to the Sun, the only terrestrial planet besides Earth with a self-sustained magnetic field, and the smallest planet in our Solar System. It is a key planet for understanding the evolutionary history of our Solar System and therefore also for the question of how the Earth and our Planetary System were formed.The scientific objectives focus on a global characterization of Mercury through the investigation of its interior, surface, exosphere, and magnetosphere. In addition, instrumentation onboard BepiColombo will be used to test Einstein’s theory of general relativity. Major effort was put into optimizing the scientific return of the mission by defining a payload such that individual measurements can be interrelated and complement each other.

Published

2021

3. Cometary plasma science -- A white paper in response to the voyage 2050 call by the European space agency

Author

Götz, C, Gunell, H, Volwerk, M, Beth, A, Eriksson, A, Galand, M, Henri, P, Nilsson, H, Wedlund, CS, Alho, M, Andersson, L, Andre, N, Keyser, JD, Deca, J, Ge, Y, Glaßmeier, K-H, Hajra, R, Karlsson, T, Kasahara, S, Kolmasova, I, LLera, K, Madanian, H, Mann, I, Mazelle, C, Odelstad, E, Plaschke, F, Rubin, M, Sanchez-Cano, B, Snodgrass, C, and Vigren, E

Subjects

Physics::Space Physics, astro-ph.EP, Astrophysics::Earth and Planetary Astrophysics

Abstract

Comets hold the key to the understanding of our solar system, its formation and its evolution, and to the fundamental plasma processes at work both in it and beyond it. A comet nucleus emits gas as it is heated by the sunlight. The gas forms the coma, where it is ionised, becomes a plasma and eventually interacts with the solar wind. Besides these neutral and ionised gases, the coma also contains dust grains, released from the comet nucleus. As a cometary atmosphere develops when the comet travels through the solar system, large-scale structures, such as the plasma boundaries, develop and disappear, while at planets such large-scale structures are only accessible in their fully grown, quasi-steady state. In situ measurements at comets enable us to learn both how such large-scale structures are formed or reformed and how small-scale processes in the plasma affect the formation and properties of these large scale structures. Furthermore, a comet goes through a wide range of parameter regimes during its life cycle, where either collisional processes, involving neutrals and charged particles, or collisionless processes are at play, and might even compete in complicated transitional regimes. Thus a comet presents a unique opportunity to study this parameter space, from an asteroid-like to a Mars- and Venus-like interaction. Fast flybys of comets have made many new discoveries, setting the stage for a multi-spacecraft mission to accompany a comet on its journey through the solar system. This white paper reviews the present-day knowledge of cometary plasmas, discusses the many questions that remain unanswered, and outlines a multi-spacecraft ESA mission to accompany a comet that will answer these questions by combining both multi-spacecraft observations and a rendezvous mission, and at the same time advance our understanding of fundamental plasma physics and its role in planetary systems.

Published

2019

4. Spatial distribution of low-energy plasma around 2 comet 67P/CG from Rosetta measurements

Author

Carr, CM, Edberg, NJT, Eriksson, AI, Odelstad, E, Henri, P, Lebreton, J-P, Gasc, S, Rubin, M, Andre, M, Gill, R, Johansson, EPG, Johansson, F, Vigren, E, Wahlund, JE, Cupido, E, Glassmeier, K-H, Goldstein, R, Koenders, C, Mandt, K, Nemeth, Z, Nilsson, H, Richter, I, Stenberg Wieser, G, Szego, K, and Volwerk, M

Published

2015

5. Multiple Flux Rope Events at the High-Latitude Magnetopause on January 26, 2001: Current Density Calculation

Author

Z. Y. Huang, Theodore A. Fritz, Chijie Xiao, Tao Chen, Jiankui Shi, Zu-Yin Pu, Li Lu, Lun Xie, Sui-Yan Fu, Zhenxing Liu, Chao Shen, Jinbin Cao, Nai‐Quan Wang, Glassmeier K‐H, and Qiugang Zong

Subjects

Physics, Flux, General Medicine, Geophysics, Mechanics, Magnetic field, Orientation (geometry), Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Magnetopause, Linear approximation, Current (fluid), Current density, Rope

Abstract

A systematic comparison is carried out for three methods of current density calculation based on simultaneous magnetic field measurements of four-spacecraft Cluster mission. It is demonstrated analytically and numerically that within the linear approximation, all these methods lead to exactly the same results. As a case study, the current density of multiple flux rope events at the high-latitude magnetopause on January 26, 2001 is investigated. The result shows that an intense current flows inside the ropes with the current density reaching as high as about 10−8A/m2. The current inside rope is valuable with small relative errors. It is also found that the current direction is almost parallel to the axis of flux rope obtained through the magnetic minimum variance analysis (BMVA). Finally, it is proposed that the current MVA method (CMVA) has great effectness for study of flux rope geometry, particularly when the BMVA is insufficient to determine the flux rope orientation.

Published

2004

6. A Mobile Asteroid Surface Scout (MASCOT) for the Hayabusa 2 Mission

Author

Jaumann, R., Bibring, J. P., Glassmeier, K. H., Grott, M., Ho, T. M., Ulamec, S., Schmitz, Nicole, Auster, H. U., Biele, J., Kuninaka, H., Okada, T., Yoshikawa, M., Watanabe, S., Fujimoto, M., Spohn, Tilman, and Mueller, N.

Subjects

Planetengeologie, asteroid, Planetenphysik, MASCOT, Leitungsbereich PF, Explorationssysteme, Planetare Sensorsysteme, Hayabusa 2 mission, sample return, Hayabusa-2, Nutzerzentrum für Weltraumexperimente (MUSC)

Published

2013

7. A Mobile Asteroid Surface Scout (MASCOT) for the Hayabusa 2 Mission to 1999 JU3: The Scientific Approach

Author

Jaumann, R., Bibring, J. P., Glassmeier, K. H., Grott, M., Ho, T.-M., Ulamec, S., Schmitz, Nicole, Auster, H. U., Biele, J., Kuninaka, H., Okada, T., Yoshikawa, M., Watanabe, S., Fujimoto, M., and Spohn, Tilman

Subjects

Hayabusa 2, MASCOT, Mascot C-type 1999 JU3

Published

2013

8. Direct evidence for a three-dimensional magnetic flux rope flanked by two active magnetic reconnection X lines at Earth's magnetopause

Author

Oieroset, M., Phan, T. D., Eastwood, J. P., Daughton, W., Shay, M. A., Angelopoulos, V., Mozer, F. S., McFadden, J. P., Larson, D. E., Glassmeier, K.-H., and Fujimoto, Masaki

Subjects

Physics, Astrophysics::High Energy Astrophysical Phenomena, General Physics and Astronomy, Magnetic reconnection, Magnetic flux, Nanoflares, L-shell, Computational physics, Magnetic field, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Magnetopause, Magnetosphere particle motion, Rope

Abstract

著者人数: 11名, 資料番号: SA1003176000

Published

2011

9. Science Rationale for an IO Volcano Observer (IVO) Mission

Author

McEwen, A., Turtle, E., Keszthelyi, L., Spencer, J., Thomas, N., Wurz, P., Christensen, P., Khurana, K., Glassmeier, K.-H., Auster, U., Furfaro, R., Davies, A., Nimmo, F., Moses, J., Bagenal, F., Kirk, R., Wieser, M., Barabash, S., Paranicus, C., Lorenz, R., Anderson, B., Showman, A., and Sandel, B.

Subjects

520 Astronomy, 620 Engineering

Published

2010

10. DuneXpress

Author

Grün, E., Srama, R., Altobelli, N., Altwegg, K., Carpenter, J., Colangeli, L., Glassmeier, K.-H., Helfert, S., Henkel, H., Horanyi, M., Jäckel, A., Kempf, S., Landgraf, M., McBride, N., Moragas-Klostermeyer, G., Palumbo, P., Scholten, H., Srowig, A., Sternovsky, Z., and Vo, X.

Published

2009

11. Lunar Exploration Orbiter (LEO): Providing a Globally Covered, Highly Resolved Integrated, Geological, Geochemical and Geophysical Data Base of the Moon

Author

Jaumann, R., Spohn, T., Hiesinger, H., Jessberger, E.K., Neukum, G., Oberst, J., Helbert, J., Christensen, U., Keller, H.U., Mall, U., Böhnhardt, H., Hartogh, P., Glassmeier, K.-H., Auster, H.-U., Moreira, A., Werner, M., Pätzold, M., Palme, H., Wimmer-Schweingruber, R., Mandea, M., Flechtner, F., Lesur, V., Häusler, B., Srama, R., Kempf, S., Hördt, A., Eichentopf, K., Hauber, E., Hoffmann, H., Köhler, U., Kührt, E., Michaelis, H., Pauer, M., Sohl, F., Denk, T., and van Gasselt, S.

Subjects

Institut für Planetenforschung, LEO, 550 - Earth sciences, Solar System, orbiter, MOON

Abstract

The German initiative for the Lunar Exploration Orbiter (LEO) originated from the national conference “Exploration of our Solar System”, held in Dresden in November 2006. Major result of this conference was that the Moon is of high interest for the scientific community for various reasons, it is affordable to perform an orbiting mission to Moon and it insures technological and scientific progress necessary to assist further exploration activities of our Solar System. Based on scientific proposals elaborated by 50 German scientists in January 2007, a preliminary payload of 12 instruments was defined. Further analysis were initated by DLR in the frame of two industry contracts, to perform a phase-zero mission definition. The Moon, our next neighbour in the Solar System is the first choice to learn, how to work and live without the chance of immediate support from earth and to get prepared for further and farther exploration missions. We have to improve our scientific knowledge base with respect to the Moon applying modern and state of the art research tools and methods. LEO is planed to be launched in 2012 and shall orbit the Moon for about four years in a low altitude orbit.

Published

2007

12. Numerical simulations on shock-like ion thruster neutralization

Author

Othmer, C., Glassmeier, K. H., Motschmann, U., Schüle, J., and Frick, Ch.

Published

2001

13. From comets to planetary satellites: specific problems in 3D bi-ion fluid simulations of Titans plasma environment

Author

Bogdanov, A.T., Glassmeier, K. H., and Motschmann, U.

Published

2001

14. Relation of Magnetic Field Line Reconnection and Unstable Nongyrotropic Particle Distributions

Author

Motschmann, U. and Glassmeier, K.-H.

Subjects

magnetic reconnection, planetary magnetospheres

Published

1998

15. Dispersion and wave extinction in nongyrotropic plasmas

Author

Motschmann, U. and Glassmeier, K.-H.

Subjects

plasma physics, instabilities, wave propagation

Published

1998

16. Cometary plasma science

Author

Goetz, C., Gunell, H., Volwerk, M., Beth, A., Eriksson, A., Galand, M., Henri, P., Nilsson, H., Wedlund, C. Simon, Alho, M., Andersson, L., Andre, N., De Keyser, J., Deca, J., Ge, Y., Glassmeier, K.-H., Hajra, R., Karlsson, T., Kasahara, S., Kolmasova, I., LLera, K., Madanian, H., Mann, I., Mazelle, C., Odelstad, E., Plaschke, F., Rubin, M., Sanchez-Cano, B., Snodgrass, C., and Vigren, E.

Subjects

13. Climate action, 520 Astronomy, 620 Engineering, 7. Clean energy

Abstract

omets hold the key to the understanding of our Solar System, its formation and its evolution, and to the fundamental plasma processes at work both in it and beyond it. A comet nucleus emits gas as it is heated by the sunlight. The gas forms the coma, where it is ionised, becomes a plasma, and eventually interacts with the solar wind. Besides these neutral and ionised gases, the coma also contains dust grains, released from the comet nucleus. As a cometary atmosphere develops when the comet travels through the Solar System, large-scale structures, such as the plasma boundaries, develop and disappear, while at planets such large-scale structures are only accessible in their fully grown, quasi-steady state. In situ measurements at comets enable us to learn both how such large-scale structures are formed or reformed and how small-scale processes in the plasma affect the formation and properties of these large scale structures. Furthermore, a comet goes through a wide range of parameter regimes during its life cycle, where either collisional processes, involving neutrals and charged particles, or collisionless processes are at play, and might even compete in complicated transitional regimes. Thus a comet presents a unique opportunity to study this parameter space, from an asteroid-like to a Mars- and Venus-like interaction. The Rosetta mission and previous fast flybys of comets have together made many new discoveries, but the most important breakthroughs in the understanding of cometary plasmas are yet to come. The Comet Interceptor mission will provide a sample of multi-point measurements at a comet, setting the stage for a multi-spacecraft mission to accompany a comet on its journey through the Solar System. This White Paper, submitted in response to the European Space Agency’s Voyage 2050 call, reviews the present-day knowledge of cometary plasmas, discusses the many questions that remain unanswered, and outlines a multi-spacecraft European Space Agency mission to accompany a comet that will answer these questions by combining both multi-spacecraft observations and a rendezvous mission, and at the same time advance our understanding of fundamental plasma physics and its role in planetary systems.

17. Cross-scale: A multi-spacecraft mission to study cross-scale coupling in space plasmas

Author

Horbury, T., Louarn, P., Fujimoto, M., Baumjohann, W., Blomberg, L. G., Barabash, S., Canu, P., Glassmeier, K. -H, Koskinen, H., Nakamura, R., Owen, C., Pulkkinen, T., Roux, A., Sauvaud, J. -A, Schwartz, S. J., Svenes, K., and Andris Vaivads

18. The landing and in-situ observation of (162173) Ryugu by the MASCOT lander

Author

Ho, T. -M, Jaumann, R., Bibring, J. -P, Grott, M., Glassmeier, K. -H, Moussi, A., Auster, U., Biele, J., Cozzoni, B., Dudal, C., Fantinati, C., Grundmann, J. -T, Hercik, D., Kayal, K., Knollenberg, J., Krause, C., Küchemann, O., Lange, C., Lange, M., Lorda, L., Maibaum, M., Mimasu, Y., Cenac-Morthe, C., Pilorget, C., Okada, T., Josef Reill, Saiki, T., Sasaki, K., Schmitz, N., Toth, N., Tsuda, Y., Ulamec, S., Wolff, F., and Yoshimitsu, T.

19. Dispersion analysis of ULF waves in the foreshock using cluster data and the wave telescope technique

Author

Narita, Y., Glassmeier, K. -H, Schäfer, S., Motschmann, U., Sauer, K., Iannis Dandouras, Fornaçon, K. -H, Georgescu, E., and Rème, H.

Subjects

Magnetospheric Physics: Solar wind/magnetosphere interactions, Interplanetary Physics: Solar wind plasma, Space Plasma Physics: Waves and instabilities

20. A multi-disciplinary investigation of the jovian system

Author

Thomas, N., Baumjohann, W., Boehnhardt, H., Chassefiere, E., Cremonese, G., Glassmeier, K. H., Roos-Serote, M., Rucker, H. O., and Fred Taylor

21. Structure and dynamics of the umagnetized plasma around comet 67P/CG

Author

Pierre Henri, Xavier Vallières, Gilet, N., Hajra, R., Moré, J., Goetz, C., Richter, I., Glassmeier, K. H., Galand, M. F., Heritier, K. L., Eriksson, A. I., Nemeth, Z., Tsurutani, B., Rubin, M., Altwegg, K., and POTHIER, Nathalie

Subjects

Surfaces, [SDU] Sciences of the Universe [physics], Ices, Dust, PLANETARY SCIENCES: COMETS AND SMALL BODIES, Plasma and MHD instabilities

Abstract

At distances close enough to the Sun, when comets are characterised by a significant outgassing, the cometary neutral density may become large enough for both the cometary plasma and the cometary gas to be coupled, through ion-neutral and electron-neutral collisions. This coupling enables the formation of an unmagnetised expanding cometary ionosphere around the comet nucleus, also called diamagnetic cavity, within which the solar wind magnetic field cannot penetrate. The instruments of the Rosetta Plasma Consortium (RPC), onboard the Rosetta Orbiter, enable us to better constrain the structure, dynamics and stability of the plasma around comet 67P/CG. Recently, magnetic field measurements (RPC-MAG) have shown the existence of such a diamagnetic region around comet 67P/CG [Götz et al., 2016]. Contrary to a single, large scale, diamagnetic cavity such as what was observed around comet Halley, Rosetta have crossed several diamagnetic structures along its trajectory around comet 67P/CG. Using electron density measurements from the Mutual Impedance Probe (RPC-MIP) during the different diamagnetic cavity crossings, identified by the flux gate magnetometer (RPC-MAG), we map the unmagnetised plasma density around comet 67P/CG. Our aims is to better constrain the structure, dynamics and stability of this inner cometary plasma layer characterised by cold electrons (as witnessed by the Langmuir Probes RPC-LAP). The ionisation ratio in these unmagnetised region(s) is computed from the measured electron (RPC-MIP) and neutral gas (ROSINA/COPS) densities. In order to assess the importance of solar EUV radiation as a source of ionisation, the observed electron density will be compared to a the density expected from an ionospheric model taking into account solar radiation absorption. The crossings of diamagnetic region(s) by Rosetta show that the unmagnetised cometary plasma is particularly homogeneous, compared to the highly dynamical magnetised plasma observed in adjacent magnetised regions. Moreover, during the crossings of multiple, successive diamagnetic region(s) over time scales of tens of minutes or hours, the plasma density is almost identical in the different unmagnetised regions, suggesting that these unmagnetised regions may be a single diamagnetic structure crossed several times by Rosetta.

22. A magnetometer for the Solar Orbiter Mission

Author

Carr, C. M., Horbury, T. S., Balogh, A., Bale, S. D., Baumjohann, W., Bavassano, B., Breen, A., Burgess, D., Cargill, P. J., Crooker, N., Erdös, G., Fletcher, L., Forsyth, R. J., Giacalone, J., Glassmeier, K. -H, Hoeksema, J. T., Goldstein, M. X., Lockwood, M., Magnes, W., Maksimovic, M., Marsch, E., Matthaeus, W. H., Murphv, N., Nakariakov, V. M., Pacheco, J. R., Pincon, J. -L, Riley, P., Russell, C. T., Schwartz, S. J., Szabo, A., Thompson, M., Vainio, R., Velli, M., Vennerstrom, S., Robert Walsh, Wimmer-Schweingruber, R., Zank, G., Laboratoire d'études spatiales et d'instrumentation en astrophysique (LESIA), Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS), Physique des plasmas, and Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Université Paris Diderot - Paris 7 (UPD7)-Centre National de la Recherche Scientifique (CNRS)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris

Subjects

[PHYS.ASTR]Physics [physics]/Astrophysics [astro-ph]

Abstract

International audience

23. Ion acoustic waves observed at Comet 67P/Churyumov-Gerasimenko

Author

Gunell, H., Nilsson, H., Hamrin, N., Eriksson, A., Maggiolo, Romain, Henri, P., Altwegg, Kathrin, Tzou, C-Y, Rubin, Martin, Glassmeier, K. -H, Stenberg Wieser, G., Simon Wedlund, Cyril, Johan De Keyser, Dhooghe, Frederik, Cessateur, Gaël, Gibbons, Andrew, and POTHIER, Nathalie

Subjects

Surfaces, [SDU] Sciences of the Universe [physics], Ices, Dust, PLANETARY SCIENCES: COMETS AND SMALL BODIES, Plasma and MHD instabilities

Abstract

We present observations of ion acoustic waves at Comet 67P/Churyumov-Gerasimenko performed on 20 January 2015 when the Rosetta spacecraft was located near the terminator, 28 km from the nucleus of the comet. At the time of the observations the activity of the comet was still low. We use distribution functions obtained by the Ion Composition Analyser of the Rosetta Plasma Consortium (RPC-ICA) and electron temperature estimatesfrom the Langmuir Probes (RPC-LAP) to compute dispersion relations for waves on the ion timescale, and compare the results to spectra obtained by RPC-LAP. The peaks of the wave spectra appear at frequencies near 500 Hz. We perform cross-calibrations between RPC-ICA, RPC-LAP, and the Mutual Impedance Probe (RPC-MIP). Matching the dispersion relations to the wave observations helps us to form an estimate of the plasma density. At times when there is significant wave activity the water ion distribution is constituted by a cold (0.01 eV) population of locally produced ions and a thin tail of ions that have been accelerated by an electric field. The tail is approximately unidirectional, covering a wide velocity range, and centred at 20km/s in the spacecraft frame. At other times a warm (approximately 1 eV), mainly isotropic, ion population renders the ion acoustic mode heavily damped, and no waves are observed. Observations of the neutral density by the ROSINA COPS instrument indicate that frictional heating by the radial neutral flow contributes to this warm ion population. This work was supported by the Belgian Science Policy Office through the Solar-Terrestrial Centre of Excellence and by PRODEX/ROSETTA/ROSINA PEA 4000107705.

24. 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., Stephan Buchert, Acuña, M. H., Fairfield, D. H., Slavin, J. A., Riedler, W., Schwingenschuh, K., and Kivelson, M. G.