Your search keyword '"Goetz C"' showing total 23 results

1. Magnetic Holes in the Solar Wind and Magnetosheath Near Mercury

Author

Karlsson, T., Heyner, D., Volwerk, M., Morooka, Michiko, Plaschke, F., Goetz, C., Hadid, L., Karlsson, T., Heyner, D., Volwerk, M., Morooka, Michiko, Plaschke, F., Goetz, C., and Hadid, L.

Abstract

We present a comprehensive statistical study of magnetic holes, defined as localized decreases of the magnetic field strength of at least 50%, in the solar wind near Mercury, using MESSENGER orbital data. We investigate the distributions of several properties of the magnetic holes, such as scale size, depth, and associated magnetic field rotation. We show that the distributions are very similar for linear magnetic holes (with a magnetic field rotation across the magnetic holes of less than 25 degrees) and rotational holes (rotations >25 degrees), except for magnetic holes with very large rotations (greater than or similar to 140 degrees). Solar wind magnetic hole scale sizes follow a log-normal distribution, which we discuss in terms of multiplicative growth. We also investigate the background magnetic field strength of the solar wind surrounding the magnetic holes, and conclude that it is lower than the average solar wind magnetic field strength. This is consistent with finding solar wind magnetic holes in high-beta regions, as expected if magnetic holes have a connection to magnetic mirror mode structures. We also present, for the first time, comprehensive statistics of isolated magnetic holes in a planetary magnetosheath. The properties of the magnetosheath magnetic holes are very similar to the solar wind counterparts, and we argue that the most likely interpretation is that the magnetosheath magnetic holes have a solar wind origin, rather than being generated locally in the magnetosheath.

Published

2021

2. Plasma Density and Magnetic Field Fluctuations in the Ion Gyro-Frequency Range Near the Diamagnetic Cavity of Comet 67P

Author

Odelstad, Elias, Eriksson, Anders, André, Mats, Graham, Daniel B., Karlsson, T., Vaivads, A., Vigren, Erik, Goetz, C., Nilsson, H., Henri, P., Stenberg-Wieser, G., Odelstad, Elias, Eriksson, Anders, André, Mats, Graham, Daniel B., Karlsson, T., Vaivads, A., Vigren, Erik, Goetz, C., Nilsson, H., Henri, P., and Stenberg-Wieser, G.

Abstract

We report the detection of large-amplitude, quasi-harmonic density fluctuations with associated magnetic field oscillations in the region surrounding the diamagnetic cavity of comet 67P. Typical frequencies are similar to 0.1 Hz, corresponding to similar to 10 times the water and less than or similar to 0.5 times the proton gyro-frequencies, respectively. Magnetic field oscillations are not always clearly observed in association with these density fluctuations, but when they are, they consistently have wave vectors perpendicular to the background magnetic field, with the principal axis of polarization close to field-aligned and with a similar to 90 degrees phase shift with respect to the density fluctuations. The fluctuations are observed in association with asymmetric plasma density and magnetic field enhancements previously found in the region surrounding the diamagnetic cavity, occurring predominantly on their descending slopes. This is a new type of waves not previously observed at comets. They are likely ion Bernstein waves, and we propose that they are excited by unstable ring, ring-beam, or spherical shell distributions of cometary ions just outside the cavity boundary. These waves may play an important role in redistributing energy between different particle populations and reshape the plasma environment of the comet.

Published

2020

3. Momentum and Pressure Balance of a Comet Ionosphere

Author

Williamson, H. N., Nilsson, H., Wieser, G. Stenberg, Eriksson, A. , I, Richter, I, Goetz, C., Williamson, H. N., Nilsson, H., Wieser, G. Stenberg, Eriksson, A. , I, Richter, I, and Goetz, C.

Abstract

We calculate the momentum flux and pressure of ions measured by the Ion Composition Analyzer (ICA) on the Rosetta mission at comet 67P/Churyumov-Gerasimenko. The total momentum flux stays roughly constant over the mission, but the contributions of different ion populations change depending on heliocentric distance. The magnetic pressure, calculated from Rosetta magnetometer measurements, roughly corresponds with the cometary ion momentum flux. When the spacecraft enters the solar wind ion cavity, the solar wind fluxes drop drastically, while the cometary momentum flux becomes roughly 10 times the solar wind fluxes outside of the ion cavity, indicating that pickup ions behave similarly to the solar wind ions in this region. We use electron density from the Langmuir probe to calculate the electron pressure, which is particularly important close to the comet nucleus where flow changes from antisunward to radially outward.

Published

2020

4. Properties of the singing comet waves in the 67P/Churyumov-Gerasimenko plasma environment as observed by the Rosetta mission

Author

Breuillard, H., Henri, P., Bucciantini, L., Volwerk, M., Karlsson, T., Eriksson, Anders, Johansson, Fredrik, Odelstad, E., Richter, I, Goetz, C., Vallieres, X., Hajra, R., Breuillard, H., Henri, P., Bucciantini, L., Volwerk, M., Karlsson, T., Eriksson, Anders, Johansson, Fredrik, Odelstad, E., Richter, I, Goetz, C., Vallieres, X., and Hajra, R.

Abstract

Using in situ measurements from different instruments on board the Rosetta spacecraft, we investigate the properties of the newly discovered low-frequency oscillations, known as singing comet waves, that sometimes dominate the close plasma environment of comet 67P/Churyumov-Gerasimenko. These waves are thought to be generated by a modified ion-Weibel instability that grows due to a beam of water ions created by water molecules that outgass from the comet. We take advantage of a cometary outburst event that occurred on 2016 February 19 to probe this generation mechanism. We analyze the 3D magnetic field waveforms to infer the properties of the magnetic oscillations of the cometary ion waves. They are observed in the typical frequency range (similar to 50 mHz) before the cometary outburst, but at similar to 20 mHz during the outburst. They are also observed to be elliptically right-hand polarized and to propagate rather closely (similar to 0-50 degrees) to the background magnetic field. We also construct a density dataset with a high enough time resolution that allows us to study the plasma contribution to the ion cometary waves. The correlation between plasma and magnetic field variations associated with the waves indicates that they are mostly in phase before and during the outburst, which means that they are compressional waves. We therefore show that the measurements from multiple instruments are consistent with the modified ion-Weibel instability as the source of the singing comet wave activity. We also argue that the observed frequency of the singing comet waves could be a way to indirectly probe the strength of neutral plasma coupling in the 67P environment.

Published

2019

5. Unusually high magnetic fields in the coma of 67P/Churyumov-Gerasimenko during its high-activity phase

Author

Goetz, C., Tsurutani, B. T., Henri, P., Volwerk, M., Behar, E., Edberg, Niklas J. T., Eriksson, Anders, Goldstein, R., Mokashi, P., Nilsson, H., Richter, I, Wellbrock, A., Glassmeier, K. H., Goetz, C., Tsurutani, B. T., Henri, P., Volwerk, M., Behar, E., Edberg, Niklas J. T., Eriksson, Anders, Goldstein, R., Mokashi, P., Nilsson, H., Richter, I, Wellbrock, A., and Glassmeier, K. H.

Abstract

Aims: On July 3, 2015, an unprecedented increase in the magnetic field magnitude was measured by the Rosetta spacecraft orbiting comet 67P/Churyumov-Gerasimenko (67P). This increase was accompanied by large variations in magnetic field and ion and electron density and energy. To our knowledge, this unusual event marks the highest magnetic field ever measured in the plasma environment of a comet. Our goal here is to examine possible physical causes for this event, and to explain this reaction of the cometary plasma and magnetic field and its trigger. Methods: We used observations from the entire Rosetta Plasma Consortium as well as energetic particle measurements from the Standard Radiation Monitor on board Rosetta to characterize the event. To provide context for the solar wind at the comet, observations at Earth were compared with simulations of the solar wind. Results: We find that the unusual behavior of the plasma around 67P is of solar wind origin and is caused by the impact of an interplanetary coronal mass ejection, combined with a corotating interaction region. This causes the magnetic field to pile up and increase by a factor of six to about 300 nT compared to normal values of the enhanced magnetic field at a comet. This increase is only partially accompanied by an increase in plasma density and energy, indicating that the magnetic field is connected to different regions of the coma.

Published

2019

6. First observations of magnetic holes deep within the coma of a comet

Author

Plaschke, F., Karlsson, T., Goetz, C., Moestl, C., Richter, I., Volwerk, M., Eriksson, Anders, Behar, E., and Goldstein, R.

Subjects

Astronomi, astrofysik och kosmologi, instabilities, Astrophysics::High Energy Astrophysical Phenomena, Physics::Space Physics, Astrophysics::Solar and Stellar Astrophysics, Astronomy, Astrophysics and Cosmology, Astrophysics::Earth and Planetary Astrophysics, interplanetary medium, plasmas - magnetohydrodynamics (MHD), general [comets]

Abstract

The Rosetta spacecraft of the European Space Agency made ground-breaking observations of comet 67P/Churyumov-Gerasimenko and of its cometary environment. We search for magnetic holes in that environment, i.e., significant depressions in the magnetic field strength, measured by the Rosetta fluxgate Magnetometer (MAG) in April and May 2015. In that time frame of two months, we identified 23 magnetic holes. The cometary activity was intermediate and increasing because Rosetta was on the inbound leg toward the Sun. While in April solar wind protons were still observed by Rosetta near the comet, in May these protons were already mostly replaced by heavy cometary ions. Magnetic holes have frequently been observed in the solar wind. We find, for the first time, that magnetic holes exist in the cometary environment even when solar wind protons are almost absent. Some of the properties of the magnetic holes are comparable to those of solar wind holes; they are associated with density enhancements, sometimes associated with co-located current sheets and fast solar wind streams, and are of similar scales. However, particularly in May, the magnetic holes near the comet appear to be more processed, featuring shifted density enhancements and, sometimes, bipolar signatures in magnetic field strength rather than simple depressions. The magnetic holes are of global size with respect to the coma. However, at the comet, they are compressed owing to magnetic field pile-up and draping so that they change in shape. There, the magnetic holes become of comparable size to heavy cometary ion gyroradii, potentially enabling kinetic interactions.

Published

2018

7. Size of a plasma cloud matters The polarisation electric field of a small-scale comet ionosphere

Author

Nilsson, H., Gunell, H., Karlsson, T., Brenning, N., Henri, P., Goetz, C., Eriksson, Anders I., Behar, E., Wieser, G. Stenberg, Vallieres, X., Nilsson, H., Gunell, H., Karlsson, T., Brenning, N., Henri, P., Goetz, C., Eriksson, Anders I., Behar, E., Wieser, G. Stenberg, and Vallieres, X.

Abstract

Context. The cometary ionosphere is immersed in fast flowing solar wind. A polarisation electric field may arise for comets much smaller than the gyroradius of pickup ions because ions and electrons respond differently to the solar wind electric field. Aims. A situation similar to that found at a low activity comet has been modelled for barium releases in the Earth's ionosphere. We aim to use such a model and apply it to the case of comet 67P Churyumov-Gerasimenko, the target of the Rosetta mission. We aim to explain the significant tailward acceleration of cometary ions through the modelled electric field. Methods. We obtained analytical solutions for the polarisation electric field of the comet ionosphere using a simplified geometry. This geometry is applicable to the comet in the inner part of the coma as the plasma density integrated along the magnetic field line remains rather constant. We studied the range of parameters for which a significant tailward electric field is obtained and compare this with the parameter range observed. Results. Observations of the local plasma density and magnetic field strength show that the parameter range of the observations agree very well with a significant polarisation electric field shielding the inner part of the coma from the solar wind electric field. Conclusions. The same process gives rise to a tailward directed electric field with a strength of the order of 10% of the solar wind electric field. Using a simple cloud model we have shown that the polarisation electric field, which arises because of the small size of the comet ionosphere as compared to the pick up ion gyroradius, can explain the observed significant tailward acceleration of cometary ions and is consistent with the observed lack of influence of the solar wind electric field in the inner coma.

Published

2018

8. Extremely Low-Frequency Waves Inside the Diamagnetic Cavity of Comet 67P/Churyumov-Gerasimenko

Author

Madsen, B., Wedlund, C. Simon, Eriksson, Anders, Goetz, C., Karlsson, T., Gunell, H., Spicher, A., Henri, P., Vallieres, X., Miloch, W. J., Madsen, B., Wedlund, C. Simon, Eriksson, Anders, Goetz, C., Karlsson, T., Gunell, H., Spicher, A., Henri, P., Vallieres, X., and Miloch, W. J.

Abstract

The European Space Agency/Rosetta mission to comet 67P/Churyumov‐Gerasimenko has provided several hundred observations of the cometary diamagnetic cavity induced by the interaction between outgassed cometary particles, cometary ions, and the solar wind magnetic field. Here we present the first electric field measurements of four preperihelion and postperihelion cavity crossings on 28 May 2015 and 17 February 2016, using the dual‐probe electric field mode of the Langmuir probe (LAP) instrument of the Rosetta Plasma Consortium. We find that on large scales, variations in the electric field fluctuations capture the cavity and boundary regions observed in the already well‐studied magnetic field, suggesting the electric field mode of the LAP instrument as a reliable tool to image cavity crossings. In addition, the LAP electric field mode unravels for the first time extremely low‐frequency waves within two cavities. These low‐frequency electrostatic waves are likely triggered by lower‐hybrid waves observed in the surrounding magnetized plasma.

Published

2018

9. Plasma Density Structures at Comet 67P/Churyumov-Gerasimenko

Author

Engelhardt, Ilka. A. D., Eriksson, Anders, Stenberg Wieser, G., Goetz, C., Rubin, M., Henri, P., Nilsson, H., Odelstad, Elias, Hajra, R., Valliéres, X., Engelhardt, Ilka. A. D., Eriksson, Anders, Stenberg Wieser, G., Goetz, C., Rubin, M., Henri, P., Nilsson, H., Odelstad, Elias, Hajra, R., and Valliéres, X.

Abstract

We present Rosetta RPC case study from four events at various radial distance, phase angle and local time from autumn 2015, just after perihelion of comet 67P/Churyumov-Gerasimenko. Pulse like (high amplitude, up to minutes in time) signatures are seen with several RPC instruments in the plasma density (LAP, MIP), ion energy and flux (ICA) as well as magnetic field intensity (MAG). Furthermore the cometocentric distance relative to the electron exobase is seen to be a good organizing parameter for the measured plasma variations. The closer Rosetta is to this boundary, the more pulses are measured. This is consistent with the pulses being filaments of plasma originating from the diamagnetic cavity boundary as predicted by simulations.

Published

2018

10. Interplanetary coronal mass ejection observed at STEREO-A, Mars, comet 67P/Churyumov-Gerasimenko, Saturn, and New Horizons en route to Pluto : Comparison of its Forbush decreases at 1.4, 3.1, and 9.9 AU

Author

Witasse, O, Sanchez-Cano, B, Mays, ML, Kajdic, P, Opgenoorth, H, Elliott, HA, Richardson, IG, Zouganelis, I, Zender, J, Wimmer-Schweingruber, RF, Turc, L, Taylor, MGGT, Roussos, E, Rouillard, A, Richter, I, Richardson, JD, Ramstad, R, Provan, G, Posner, A, Plaut, JJ, Odstrcil, D, Nilsson, H, Niemenen, P, Milan, SE, Mandt, K, Lohf, H, Lester, M, Lebreton, J-P, Kuulkers, E, Krupp, N, Koenders, C, James, MK, Intzekara, D, Holmstrom, M, Hassler, DM, Hall, BES, Guo, J, Goldstein, R, Goetz, C, Glassmeier, KH, Genot, V, Evans, H, Espley, J, Edberg, NJT, Dougherty, M, Cowley, SWH, Burch, J, Behar, E, Barabash, S, Andrews, DJ, and Altobelli, N

Subjects

COROTATING INTERACTION REGIONS, COSMIC-RAY MODULATION, Science & Technology, 3-DIMENSIONAL PROPAGATION, PARTICLE-ACCELERATION, INSTRUMENT, ROSETTA PLASMA CONSORTIUM, ENERGETIC PARTICLES, MAGNETIC CLOUDS, Mars, comet 67P, Astronomy & Astrophysics, New Horizons, Saturn, Astronomi, astrofysik och kosmologi, SOLAR-WIND, Physical Sciences, Astronomy, Astrophysics and Cosmology, interplanetary coronal mass ejection, VOYAGER-2 OBSERVATIONS, Forbush decrease

Abstract

We discuss observations of the journey throughout the Solar System of a large interplanetary coronal mass ejection (ICME) that was ejected at the Sun on 14 October 2014. The ICME hit Mars on 17 October, as observed by the Mars Express, Mars Atmosphere and Volatile EvolutioN Mission (MAVEN), Mars Odyssey, and Mars Science Laboratory (MSL) missions, 44h before the encounter of the planet with the Siding-Spring comet, for which the space weather context is provided. It reached comet 67P/Churyumov-Gerasimenko, which was perfectly aligned with the Sun and Mars at 3.1 AU, as observed by Rosetta on 22 October. The ICME was also detected by STEREO-A on 16 October at 1 AU, and by Cassini in the solar wind around Saturn on the 12 November at 9.9AU. Fortuitously, the New Horizons spacecraft was also aligned with the direction of the ICME at 31.6 AU. We investigate whether this ICME has a nonambiguous signature at New Horizons. A potential detection of this ICME by Voyager 2 at 110-111 AU is also discussed. The multispacecraft observations allow the derivation of certain properties of the ICME, such as its large angular extension of at least 116 degrees, its speed as a function of distance, and its magnetic field structure at four locations from 1 to 10 AU. Observations of the speed data allow two different solar wind propagation models to be validated. Finally, we compare the Forbush decreases (transient decreases followed by gradual recoveries in the galactic cosmic ray intensity) due to the passage of this ICME at Mars, comet 67P, and Saturn.

Published

2017

11. Diamagnetic region(s) : structure of the unmagnetized plasma around Comet 67P/CG

Author

Henri, P., Vallieres, X., Hajra, R., Goetz, C., Richter, I., Glassmeier, K. -H, Galand, M., Rubin, M., Eriksson, Anders I., Nemeth, Z., Vigren, Erik, Beth, A., Burch, J. L., Carr, C., Nilsson, H., Tsurutani, B., Wattieaux, G., Henri, P., Vallieres, X., Hajra, R., Goetz, C., Richter, I., Glassmeier, K. -H, Galand, M., Rubin, M., Eriksson, Anders I., Nemeth, Z., Vigren, Erik, Beth, A., Burch, J. L., Carr, C., Nilsson, H., Tsurutani, B., and Wattieaux, G.

Abstract

The ESA's comet chaser Rosetta has monitored the evolution of the ionized atmosphere of comet 67P/Churyumov-Gerasimenko (67P/CG) and its interaction with the solar wind, during more than 2 yr. Around perihelion, while the cometary outgassing rate was highest, Rosetta crossed hundreds of unmagnetized regions, but did not seem to have crossed a large-scale diamagnetic cavity as anticipated. Using in situ Rosetta observations, we characterize the structure of the unmagnetized plasma found around comet 67P/CG. Plasma density measurements from RPC-MIP are analysed in the unmagnetized regions identified with RPC-MAG. The plasma observations are discussed in the context of the cometary escaping neutral atmosphere, observed by ROSINA/COPS. The plasma density in the different diamagnetic regions crossed by Rosetta ranges from similar to 100 to similar to 1500 cm(-3). They exhibit a remarkably systematic behaviour that essentially depends on the comet activity and the cometary ionosphere expansion. An effective total ionization frequency is obtained from in situ observations during the high outgassing activity phase of comet 67P/CG. Although several diamagnetic regions have been crossed over a large range of distances to the comet nucleus (from 50 to 400 km) and to the Sun (1.25-2.4 au), in situ observations give strong evidence for a single diamagnetic region, located close to the electron exobase. Moreover, the observations are consistent with an unstable contact surface that can locally extend up to about 10 times the electron exobase.

Published

2017

12. Effective ion speeds at similar to 200-250 km from comet 67P/Churyumov-Gerasimenko near perihelion

Author

Vigren, Erik, André, Mats, Edberg, Niklas J. T., Engelhardt, Ilka. A. D., Eriksson, Anders, Galand, M., Goetz, C., Henri, P., Heritier, K., Johansson, Fredrik, Nilsson, H., Odelstad, Elias, Rubin, M., Stenberg-Wieser, G., Tzou, C. -Y, Vallieres, X., Vigren, Erik, André, Mats, Edberg, Niklas J. T., Engelhardt, Ilka. A. D., Eriksson, Anders, Galand, M., Goetz, C., Henri, P., Heritier, K., Johansson, Fredrik, Nilsson, H., Odelstad, Elias, Rubin, M., Stenberg-Wieser, G., Tzou, C. -Y, and Vallieres, X.

Abstract

In 2015 August, comet 67P/Churyumov-Gerasimenko, the target comet of the ESA Rosetta mission, reached its perihelion at similar to 1.24 au. Here, we estimate for a three-day period near perihelion, effective ion speeds at distances similar to 200-250 km from the nucleus. We utilize two different methods combining measurements from the Rosetta Plasma Consortium (RPC)/Mutual Impedance Probe with measurements either from the RPC/Langmuir Probe or from the Rosetta Orbiter Spectrometer for Ion and Neutral Analysis (ROSINA)/Comet Pressure Sensor (COPS) (the latter method can only be applied to estimate the effective ion drift speed). The obtained ion speeds, typically in the range 2-8 km s(-1), are markedly higher than the expected neutral outflow velocity of similar to 1 km s(-1). This indicates that the ions were de-coupled from the neutrals before reaching the spacecraft location and that they had undergone acceleration along electric fields, not necessarily limited to acceleration along ambipolar electric fields in the radial direction. For the limited time period studied, we see indications that at increasing distances from the nucleus, the fraction of the ions' kinetic energy associated with radial drift motion is decreasing.

Published

2017

13. Plasma waves confined to the diamagnetic cavity of comet 67P/Churyumov-Gerasimenko

Author

Gunell, H., Goetz, C., Eriksson, Anders I., Nilsson, H., Wedlund, C. Simon, Henri, P., Maggiolo, R., Hamrin, M., De Keyser, J., Rubin, M., Wieser, G. Stenberg, Cessateur, G., Dhooghe, F., Gibbons, A., Gunell, H., Goetz, C., Eriksson, Anders I., Nilsson, H., Wedlund, C. Simon, Henri, P., Maggiolo, R., Hamrin, M., De Keyser, J., Rubin, M., Wieser, G. Stenberg, Cessateur, G., Dhooghe, F., and Gibbons, A.

Abstract

Ion acoustic waves were observed in the diamagnetic cavity of comet 67P/Churyumov-Gerasimenko by the Rosetta spacecraft on 2015 August 3, when the comet was 1.25 au from the Sun. Wave spectra recorded by the Langmuir probe (RPC-LAP), peak near 200 Hz, decrease for higher frequencies and reach the noise floor at approximately 1.5 kHz. These waves were observed only when the spacecraft was in the diamagnetic cavity or at its boundary, which is identified as a sharp drop in magnetic field magnitude, measured by RPC-MAG. The plasma, on both sides of the boundary, is dominated by a cold (a few hundred K) water group ion population, one cold (k(B)T(e) similar to 0.1 eV) and one warm (k(B)T(e) similar to 10 eV) electron population. The observations are interpreted in terms of current-driven ion acoustic waves, generated by currents that flow through bulges on the boundary of the diamagnetic cavity.

Published

2017

14. Impact of a cometary outburst on its ionosphere Rosetta Plasma Consortium observations of the outburst exhibited by comet 67P/Churyumov-Gerasimenko on 19 February 2016

Author

Hajra, R., Henri, P., Vallieres, X., Galand, M., Heritier, K., Eriksson, Anders I., Odelstad, Elias, Edberg, Niklas J. T., Burch, J. L., Broiles, T., Goldstein, R., Glassmeier, K. H., Richter, I., Goetz, C., Tsurutani, B. T., Nilsson, H., Altwegg, K., Rubin, M., Hajra, R., Henri, P., Vallieres, X., Galand, M., Heritier, K., Eriksson, Anders I., Odelstad, Elias, Edberg, Niklas J. T., Burch, J. L., Broiles, T., Goldstein, R., Glassmeier, K. H., Richter, I., Goetz, C., Tsurutani, B. T., Nilsson, H., Altwegg, K., and Rubin, M.

Abstract

We present a detailed study of the cometary ionospheric response to a cometary brightness outburst using in situ measurements for the first time. The comet 67P/Churyumov-Gerasimenko (67P) at a heliocentric distance of 2.4 AU from the Sun, exhibited an outburst at similar to 1000 UT on 19 February 2016, characterized by an increase in the coma surface brightness of two orders of magnitude. The Rosetta spacecraft monitored the plasma environment of 67P from a distance of 30 km, orbiting with a relative speed of similar to 0.2 m s(-1). The onset of the outburst was preceded by pre-outburst decreases in neutral gas density at Rosetta, in local plasma density, and in negative spacecraft potential at similar to 0950 UT. In response to the outburst, the neutral density increased by a factor of similar to 1.8 and the local plasma density increased by a factor of similar to 3, driving the spacecraft potential more negative. The energetic electrons (tens of eV) exhibited decreases in the flux of factors of similar to 2 to 9, depending on the energy of the electrons. The local magnetic field exhibited a slight increase in amplitude (similar to 5 nT) and an abrupt rotation (similar to 36.4 degrees) in response to the outburst. A weakening of 10-100 mHz magnetic field fluctuations was also noted during the outburst, suggesting alteration of the origin of the wave activity by the outburst. The plasma and magnetic field effects lasted for about 4 h, from similar to 1000 UT to 1400 UT. The plasma densities are compared with an ionospheric model. This shows that while photoionization is the main source of electrons, electron-impact ionization and a reduction in the ion outflow velocity need to be accounted for in order to explain the plasma density enhancement near the outburst peak.

Published

2017

15. Interplanetary coronal mass ejection observed at STEREO-A, Mars, comet 67P/Churyumov-Gerasimenko, Saturn, and New Horizons en route to Pluto : Comparison of its Forbush decreases at 1.4, 3.1, and 9.9 AU

Author

Witasse, O., Sanchez-Cano, B., Mays, M. L., Kajdic, P., Opgenoorth, Hermann, Elliott, H. A., Richardson, I. G., Zouganelis, I., Zender, J., Wimmer-Schweingruber, R. F., Turc, L., Taylor, M. G. G. T., Roussos, E., Rouillard, A., Richter, I., Richardson, J. D., Ramstad, R., Provan, G., Posner, A., Plaut, J. J., Odstrcil, D., Nilsson, H., Niemenen, P., Milan, S. E., Mandt, K., Lohf, H., Lester, M., Lebreton, J. -P, Kuulkers, E., Krupp, N., Koenders, C., James, M. K., Intzekara, D., Holmstrom, M., Hassler, D. M., Hall, B. E. S., Guo, J., Goldstein, R., Goetz, C., Glassmeier, K. H., Genot, V., Evans, H., Espley, J., Edberg, N. J. T., Edberg, Niklas J. T., Cowley, S. W. H., Burch, J., Behar, E., Barabash, S., Andrews, David J., Altobelli, N., Witasse, O., Sanchez-Cano, B., Mays, M. L., Kajdic, P., Opgenoorth, Hermann, Elliott, H. A., Richardson, I. G., Zouganelis, I., Zender, J., Wimmer-Schweingruber, R. F., Turc, L., Taylor, M. G. G. T., Roussos, E., Rouillard, A., Richter, I., Richardson, J. D., Ramstad, R., Provan, G., Posner, A., Plaut, J. J., Odstrcil, D., Nilsson, H., Niemenen, P., Milan, S. E., Mandt, K., Lohf, H., Lester, M., Lebreton, J. -P, Kuulkers, E., Krupp, N., Koenders, C., James, M. K., Intzekara, D., Holmstrom, M., Hassler, D. M., Hall, B. E. S., Guo, J., Goldstein, R., Goetz, C., Glassmeier, K. H., Genot, V., Evans, H., Espley, J., Edberg, N. J. T., Edberg, Niklas J. T., Cowley, S. W. H., Burch, J., Behar, E., Barabash, S., Andrews, David J., and Altobelli, N.

Abstract

We discuss observations of the journey throughout the Solar System of a large interplanetary coronal mass ejection (ICME) that was ejected at the Sun on 14 October 2014. The ICME hit Mars on 17 October, as observed by the Mars Express, Mars Atmosphere and Volatile EvolutioN Mission (MAVEN), Mars Odyssey, and Mars Science Laboratory (MSL) missions, 44h before the encounter of the planet with the Siding-Spring comet, for which the space weather context is provided. It reached comet 67P/Churyumov-Gerasimenko, which was perfectly aligned with the Sun and Mars at 3.1 AU, as observed by Rosetta on 22 October. The ICME was also detected by STEREO-A on 16 October at 1 AU, and by Cassini in the solar wind around Saturn on the 12 November at 9.9AU. Fortuitously, the New Horizons spacecraft was also aligned with the direction of the ICME at 31.6 AU. We investigate whether this ICME has a nonambiguous signature at New Horizons. A potential detection of this ICME by Voyager 2 at 110-111 AU is also discussed. The multispacecraft observations allow the derivation of certain properties of the ICME, such as its large angular extension of at least 116 degrees, its speed as a function of distance, and its magnetic field structure at four locations from 1 to 10 AU. Observations of the speed data allow two different solar wind propagation models to be validated. Finally, we compare the Forbush decreases (transient decreases followed by gradual recoveries in the galactic cosmic ray intensity) due to the passage of this ICME at Mars, comet 67P, and Saturn.

Published

2017

16. Current sheets in comet 67P/Churyumov-Gerasimenko's coma

Author

Volwerk, M., Jones, G. H., Broiles, T., Burch, J., Carr, C., Coates, A. J., Cupido, E., Delva, M., Edberg, Niklas J. T., Eriksson, Anders, Goetz, C., Goldstein, R., Henri, P., Madanian, H., Nilsson, H., Richter, I., Schwingenschuh, K., Wieser, G. Stenberg, Glassmeier, K. -H, Volwerk, M., Jones, G. H., Broiles, T., Burch, J., Carr, C., Coates, A. J., Cupido, E., Delva, M., Edberg, Niklas J. T., Eriksson, Anders, Goetz, C., Goldstein, R., Henri, P., Madanian, H., Nilsson, H., Richter, I., Schwingenschuh, K., Wieser, G. Stenberg, and Glassmeier, K. -H

Abstract

The Rosetta Plasma Consortium (RPC) data are used to investigate the presence of current sheets in the coma of comet 67P/Churyumov-Gerasimenko. The interaction of the interplanetary magnetic field (IMF) transported by the solar wind toward the outgassing comet consists amongst others of mass loading and field line draping near the nucleus. The draped field lines lead to so-called nested draping because of the constantly changing direction of the IMF. It is shown that the draping pattern is strongly variable over the period of one month. Nested draping results in neighbouring regions with oppositely directed magnetic fields, which are separated by current sheets. Selected events on 5 and 6 June 2015 are studied, which show that there are strong rotations of the magnetic field with associated current sheets that have strengths from several tens up to hundreds of nA/m(2). Not all discussed current sheets show the characteristic peak in plasma density at the centre of the sheet, which might be related to the presence of a guide field. There is no evidence for different kinds of plasmas on either side of a current sheet, and no strongly accelerated ions have been observed which could have been an indication of magnetic reconnection in the current sheets. Plain Language Summary The solar wind, consisting of plasma and magnetic field, cannot uninhabited flow past an active comet. The interaction of the gas coming out of the comet, which gets ionized, and the solar wind leads to a slowing down of the latter, and the magnetic field gets draped around the nucleus of the comet. As the solar wind magnetic field is not constant over time, there will be layers of different directions draped on top of each other, which leads to the generation of current sheets. In this paper the strength of the currents is determined, and signatures of possible magnetic reconnection are looked for but were not found.

Published

2017

17. CME impact on comet 67P/Churyumov-Gerasimenko

Author

Edberg, Niklas J. T., Alho, M., André, Mats, Andrews, David J., Behar, E., Burch, J. L., Carr, C. M., Cupido, E., Engelhardt, Ilka. A. D., Eriksson, Anders I., Glassmeier, K. -H, Goetz, C., Goldstein, R., Henri, P., Johansson, Fredrik L., Koenders, C., Mandt, K., Moestl, C., Nilsson, H., Odelstad, Elias, Richter, I., Wedlund, C. Simon, Wieser, G. Stenberg, Szego, K., Vigren, Erik, Volwerk, M., Edberg, Niklas J. T., Alho, M., André, Mats, Andrews, David J., Behar, E., Burch, J. L., Carr, C. M., Cupido, E., Engelhardt, Ilka. A. D., Eriksson, Anders I., Glassmeier, K. -H, Goetz, C., Goldstein, R., Henri, P., Johansson, Fredrik L., Koenders, C., Mandt, K., Moestl, C., Nilsson, H., Odelstad, Elias, Richter, I., Wedlund, C. Simon, Wieser, G. Stenberg, Szego, K., Vigren, Erik, and Volwerk, M.

Abstract

We present Rosetta observations from comet 67P/Churyumov-Gerasimenko during the impact of a coronal mass ejection (CME). The CME impacted on 2015 Oct 5-6, when Rosetta was about 800 km from the comet nucleus, and 1.4 au from the Sun. Upon impact, the plasma environment is compressed to the level that solar wind ions, not seen a few days earlier when at 1500 km, now reach Rosetta. In response to the compression, the flux of suprathermal electrons increases by a factor of 5-10 and the background magnetic field strength increases by a factor of similar to 2.5. The plasma density increases by a factor of 10 and reaches 600 cm(-3), due to increased particle impact ionization, charge exchange and the adiabatic compression of the plasma environment. We also observe unprecedentedly large magnetic field spikes at 800 km, reaching above 200 nT, which are interpreted as magnetic flux ropes. We suggest that these could possibly be formed by magnetic reconnection processes in the coma as the magnetic field across the CME changes polarity, or as a consequence of strong shears causing Kelvin-Helmholtz instabilities in the plasma flow. Due to the limited orbit of Rosetta, we are not able to observe if a tail disconnection occurs during the CME impact, which could be expected based on previous remote observations of other CME-comet interactions., QC 20200602

Published

2016

18. Mass-loading, pile-up, and mirror-mode waves at comet 67P/Churyumov-Gerasimenko

Author

Volwerk, M., Richter, I., Tsurutani, B., Goetz, C., Altwegg, K., Broiles, T., Burch, J., Carr, C., Cupido, E., Delva, M., Dosa, M., Edberg, Niklas. J. T., Eriksson, Anders, Henri, P., Koenders, C., Lebreton, J. -P, Mandt, K. E., Nilsson, H., Opitz, A., Rubin, M., Schwingenschuh, K., Wieser, G. Stenberg, Szegoe, K., Vallat, C., Vallieres, X., Glassmeier, K. -H, Volwerk, M., Richter, I., Tsurutani, B., Goetz, C., Altwegg, K., Broiles, T., Burch, J., Carr, C., Cupido, E., Delva, M., Dosa, M., Edberg, Niklas. J. T., Eriksson, Anders, Henri, P., Koenders, C., Lebreton, J. -P, Mandt, K. E., Nilsson, H., Opitz, A., Rubin, M., Schwingenschuh, K., Wieser, G. Stenberg, Szegoe, K., Vallat, C., Vallieres, X., and Glassmeier, K. -H

Abstract

The data from all Rosetta plasma consortium instruments and from the ROSINA COPS instrument are used to study the interaction of the solar wind with the outgassing cometary nucleus of 67P/Churyumov-Gerasimenko. During 6 and 7 June 2015, the interaction was first dominated by an increase in the solar wind dynamic pressure, caused by a higher solar wind ion density. This pressure compressed the draped magnetic field around the comet, and the increase in solar wind electrons enhanced the ionization of the outflow gas through collisional ionization. The new ions are picked up by the solar wind magnetic field, and create a ring/ring-beam distribution, which, in a high-beta plasma, is unstable for mirror mode wave generation. Two different kinds of mirror modes are observed: one of small size generated by locally ionized water and one of large size generated by ionization and pick-up farther away from the comet.

Published

2016

19. First detection of a diamagnetic cavity at comet 67P/Churyumov-Gerasimenko

Author

Goetz, C., Koenders, C., Richter, I., Altwegg, K., Burch, J., Carr, C., Cupido, E., Eriksson, Anders, Guettler, C., Henri, P., Mokashi, P., Nemeth, Z., Nilsson, H., Rubin, M., Sierks, H., Tsurutani, B., Vallat, C., Volwerk, M., Glassmeier, K. -H, Goetz, C., Koenders, C., Richter, I., Altwegg, K., Burch, J., Carr, C., Cupido, E., Eriksson, Anders, Guettler, C., Henri, P., Mokashi, P., Nemeth, Z., Nilsson, H., Rubin, M., Sierks, H., Tsurutani, B., Vallat, C., Volwerk, M., and Glassmeier, K. -H

Abstract

Context. The Rosetta magnetometer RPC-MAG has been exploring the plasma environment of comet 67P/Churyumov-Gerasimenko since August 2014. The first months were dominated by low-frequency waves which evolved into more complex features. However, at the end of July 2015, close to perihelion, the magnetometer detected a region that did not contain any magnetic field at all. Aims. These signatures match the appearance of a diamagnetic cavity as was observed at comet 1P/Halley in 1986. The cavity here is more extended than previously predicted by models and features unusual magnetic field configurations, which need to be explained. Methods. The onboard magnetometer data were analyzed in detail and used to estimate the outgassing rate. A minimum variance analysis was used to determine boundary normals. Results. Our analysis of the data acquired by the Rosetta Plasma Consortium instrumentation confirms the existence of a diamagnetic cavity. The size is larger than predicted by simulations, however. One possible explanation are instabilities that are propagating along the cavity boundary and possibly a low magnetic pressure in the solar wind. This conclusion is supported by a change in sign of the Sun-pointing component of the magnetic field. Evidence also indicates that the cavity boundary is moving with variable velocities ranging from 230 500m/s.

Published

2016

20. RPC observation of the development and evolution of plasma interaction boundaries at 67P/Churyumov-Gerasimenko

Author

Mandt, K. E., Eriksson, Anders, Edberg, Niklas J. T., Koenders, C., Broiles, T., Fuselier, S. A., Henri, P., Nemeth, Z., Alho, M., Biver, N., Beth, A., Burch, J., Carr, C., Chae, K., Coates, A. J., Cupido, E., Galand, M., Glassmeier, K. -H, Goetz, C., Goldstein, R., Hansen, K. C., Haiducek, J., Kallio, E., Lebreton, J. -P, Luspay-Kuti, A., Mokashi, P., Nilsson, H., Opitz, A., Richter, I., Samara, M., Szego, K., Tzou, C. -Y, Volwerk, M., Wedlund, C. Simon, Wieser, G. Stenberg, Mandt, K. E., Eriksson, Anders, Edberg, Niklas J. T., Koenders, C., Broiles, T., Fuselier, S. A., Henri, P., Nemeth, Z., Alho, M., Biver, N., Beth, A., Burch, J., Carr, C., Chae, K., Coates, A. J., Cupido, E., Galand, M., Glassmeier, K. -H, Goetz, C., Goldstein, R., Hansen, K. C., Haiducek, J., Kallio, E., Lebreton, J. -P, Luspay-Kuti, A., Mokashi, P., Nilsson, H., Opitz, A., Richter, I., Samara, M., Szego, K., Tzou, C. -Y, Volwerk, M., Wedlund, C. Simon, and Wieser, G. Stenberg

Abstract

One of the primary objectives of the Rosetta Plasma Consortium, a suite of five plasma instruments on-board the Rosetta spacecraft, is to observe the formation and evolution of plasma interaction regions at the comet 67P/Churyumov-Gerasimenko (67P/CG). Observations made between 2015 April and 2016 February show that solar wind-cometary plasma interaction boundaries and regions formed around 2015 mid-April and lasted through early 2016 January. At least two regions were observed, separated by an ion-neutral collisionopause boundary. The inner region was located on the nucleus side of the boundary and was characterized by low-energy water-group ions, reduced magnetic field pileup and enhanced electron densities. The outer region was located outside of the boundary and was characterized by reduced electron densities, water-group ions that are accelerated to energies above 100 eV and enhanced magnetic field pileup compared to the inner region. The boundary discussed here is outside of the diamagnetic cavity and shows characteristics similar to observations made on-board the Giotto spacecraft in the ion pileup region at 1P/Halley. We find that the boundary is likely to be related to ion-neutral collisions and that its location is influenced by variability in the neutral density and the solar wind dynamic pressure.

Published

2016

21. Structure and evolution of the diamagnetic cavity at comet 67P/Churyumov-Gerasimenko

Author

Goetz, C., Koenders, C., Hansen, K. C., Burch, J., Carr, C., Eriksson, Anders, Fruehauff, D., Guettler, C., Henri, P., Nilsson, H., Richter, I., Rubin, M., Sierks, H., Tsurutani, B., Volwerk, M., Glassmeier, K. H., Goetz, C., Koenders, C., Hansen, K. C., Burch, J., Carr, C., Eriksson, Anders, Fruehauff, D., Guettler, C., Henri, P., Nilsson, H., Richter, I., Rubin, M., Sierks, H., Tsurutani, B., Volwerk, M., and Glassmeier, K. H.

Abstract

The long duration of the Rosetta mission allows us to study the evolution of the diamagnetic cavity at comet 67P/Churyumov-Gerasimenko in detail. From 2015 April to 2016 February 665 intervals could be identified where Rosetta was located in a zero-magnetic-field region. We study the temporal and spatial distribution of this cavity and its boundary and conclude that the cavity properties depend on the long-term trend of the outgassing rate, but do not respond to transient events at the spacecraft location, such as outbursts or high neutral densities. Using an empirical model of the outgassing rate, we find a functional relationship between the outgassing rate and the distance of the cavity to the nucleus. There is also no indication that this unexpectedly large distance is related to unusual solar wind conditions. Because the deduced shape of the cavity boundary is roughly elliptical on small scales and the distances of the boundary from the nucleus are much larger than expected we conclude that the events observed by Rosetta are due to a moving instability of the cavity boundary itself.

Published

2016

22. The 2016 Feb 19 outburst of comet 67P/CG : an ESA Rosetta multi-instrument study

Author

Grun, E., Agarwal, J., Altobelli, N., Altwegg, K., Bentley, M. S., Biver, N., Della Corte, V., Edberg, Niklas J. T., Feldman, P. D., Galand, M., Geiger, B., Goetz, C., Grieger, B., Guettler, C., Henri, P., Hofstadter, M., Horanyi, M., Jehin, E., Krueger, H., Lee, S., Mannel, T., Morales, E., Mousis, O., Mueller, M., Opitom, C., Rotundi, A., Schmied, R., Schmidt, F., Sierks, H., Snodgrass, C., Soja, R. H., Sommer, M., Srama, R., Tzou, C. -Y, Vincent, J. -B, Yanamandra-Fisher, P., A'Hearn, M. F., Eriksson, Anders, Barbieri, C., Barucci, M. A., Bertaux, J. -L, Bertini, I., Burch, J., Colangeli, L., Cremonese, G., Da Deppo, V., Davidsson, Björn, Debei, S., De Cecco, M., Deller, J., Feaga, L. M., Ferrari, M., Fornasier, S., Fulle, M., Gicquel, A., Gillon, M., Green, S. F., Groussin, O., Gutierrez, P. J., Hofmann, M., Hviid, S. F., Ip, W. -H, Ivanovski, S., Jorda, L., Keller, H. U., Knight, M. M., Knollenberg, J., Koschny, D., Kramm, J. -R, Kuehrt, E., Kuppers, M., Lamy, P. L., Lara, L. M., Lazzarin, M., Lopez-Moreno, J. J., Manfroid, J., Epifani, E. Mazzotta, Marzari, F., Naletto, G., Oklay, N., Palumbo, P., Parker, J. Wm., Rickman, Hans, Rodrigo, R., Rodriguez, J., Schindhelm, E., Shi, X., Sordini, R., Steffl, A. J., Stern, S. A., Thomas, N., Tubiana, C., Weaver, H. A., Weissman, P., Zakharov, V. V., Grun, E., Agarwal, J., Altobelli, N., Altwegg, K., Bentley, M. S., Biver, N., Della Corte, V., Edberg, Niklas J. T., Feldman, P. D., Galand, M., Geiger, B., Goetz, C., Grieger, B., Guettler, C., Henri, P., Hofstadter, M., Horanyi, M., Jehin, E., Krueger, H., Lee, S., Mannel, T., Morales, E., Mousis, O., Mueller, M., Opitom, C., Rotundi, A., Schmied, R., Schmidt, F., Sierks, H., Snodgrass, C., Soja, R. H., Sommer, M., Srama, R., Tzou, C. -Y, Vincent, J. -B, Yanamandra-Fisher, P., A'Hearn, M. F., Eriksson, Anders, Barbieri, C., Barucci, M. A., Bertaux, J. -L, Bertini, I., Burch, J., Colangeli, L., Cremonese, G., Da Deppo, V., Davidsson, Björn, Debei, S., De Cecco, M., Deller, J., Feaga, L. M., Ferrari, M., Fornasier, S., Fulle, M., Gicquel, A., Gillon, M., Green, S. F., Groussin, O., Gutierrez, P. J., Hofmann, M., Hviid, S. F., Ip, W. -H, Ivanovski, S., Jorda, L., Keller, H. U., Knight, M. M., Knollenberg, J., Koschny, D., Kramm, J. -R, Kuehrt, E., Kuppers, M., Lamy, P. L., Lara, L. M., Lazzarin, M., Lopez-Moreno, J. J., Manfroid, J., Epifani, E. Mazzotta, Marzari, F., Naletto, G., Oklay, N., Palumbo, P., Parker, J. Wm., Rickman, Hans, Rodrigo, R., Rodriguez, J., Schindhelm, E., Shi, X., Sordini, R., Steffl, A. J., Stern, S. A., Thomas, N., Tubiana, C., Weaver, H. A., Weissman, P., and Zakharov, V. V.

Abstract

On 2016 Feb 19, nine Rosetta instruments serendipitously observed an outburst of gas and dust from the nucleus of comet 67P/Churyumov-Gerasimenko. Among these instruments were cameras and spectrometers ranging from UV over visible to microwave wavelengths, in situ gas, dust and plasma instruments, and one dust collector. At 09: 40 a dust cloud developed at the edge of an image in the shadowed region of the nucleus. Over the next two hours the instruments recorded a signature of the outburst that significantly exceeded the background. The enhancement ranged from 50 per cent of the neutral gas density at Rosetta to factors > 100 of the brightness of the coma near the nucleus. Dust related phenomena (dust counts or brightness due to illuminated dust) showed the strongest enhancements (factors > 10). However, even the electron density at Rosetta increased by a factor 3 and consequently the spacecraft potential changed from similar to-16 V to -20 V during the outburst. A clear sequence of events was observed at the distance of Rosetta ( 34 km from the nucleus): within 15 min the Star Tracker camera detected fast particles (similar to 25 m s(-1)) while 100 mu m radius particles were detected by the GIADA dust instrument similar to 1 h later at a speed of 6 m s(-1). The slowest were individual mm to cm sized grains observed by the OSIRIS cameras. Although the outburst originated just outside the FOV of the instruments, the source region and the magnitude of the outburst could be determined.

Published

2016

23. Observation of a new type of low-frequency waves at comet 67P/Churyumov-Gerasimenko

Author

Richter, I., Koenders, C., Auster, H. -U, Fruehauff, D., Goetz, C., Heinisch, P., Perschke, C., Motschmann, U., Stoll, B., Altwegg, K., Burch, J., Carr, C., Cupido, E., Eriksson, Anders, Henri, P., Goldstein, R., Lebreton, J. -P, Mokashi, P., Nemeth, Z., Nilsson, H., Rubin, M., Szegoe, K., Tsurutani, B. T., Vallat, C., Volwerk, M., Glassmeier, K. -H, Richter, I., Koenders, C., Auster, H. -U, Fruehauff, D., Goetz, C., Heinisch, P., Perschke, C., Motschmann, U., Stoll, B., Altwegg, K., Burch, J., Carr, C., Cupido, E., Eriksson, Anders, Henri, P., Goldstein, R., Lebreton, J. -P, Mokashi, P., Nemeth, Z., Nilsson, H., Rubin, M., Szegoe, K., Tsurutani, B. T., Vallat, C., Volwerk, M., and Glassmeier, K. -H

Abstract

We report on magnetic field measurements made in the innermost coma of 67P/Churyumov-Gerasimenko in its low-activity state. Quasi-coherent, large-amplitude (delta B/B similar to 1), compressional magnetic field oscillations at similar to 40 mHz dominate the immediate plasma environment of the nucleus. This differs from previously studied cometary interaction regions where waves at the cometary ion gyro-frequencies are the main feature. Thus classical pickup-ion-driven instabilities are unable to explain the observations. We propose a cross-field current instability associated with newborn cometary ion currents as a possible source mechanism.

Published

2015