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1. BepiColombo observations of cold oxygen and carbon ions in the flank of the induced magnetosphere of Venus

Author

Hadid, L. Z., Delcourt, D., Saito, Y., Fränz, M., Yokota, S., Fiethe, B., Verdeil, C., Katra, B., Leblanc, F., Fischer, H., Persson, M., Aizawa, S., André, N., Harada, Y., Fedorov, A., Fontaine, D., Krupp, N., Michalik, H., Berthelier, J-J., Krüger, H., Murakami, G., Matsuda, S., Heyner, D., Auster, H.-U., Richter, I., Mieth, J. Z. D., Schmid, D., and Fischer, D.

Published
2024
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2. The 17 April 2021 widespread solar energetic particle event

Author

Dresing, N., Rodríguez-García, L., Jebaraj, I. C., Warmuth, A., Wallace, S., Balmaceda, L., Podladchikova, T., Strauss, R. D., Kouloumvakos, A., Palmroos, C., Krupar, V., Gieseler, J., Xu, Z., Mitchell, J. G., Cohen, C. M. S., de Nolfo, G. A., Palmerio, E., Carcaboso, F., Kilpua, E. K. J., Trotta, D., Auster, U., Asvestari, E., da Silva, D., Dröge, W., Getachew, T., Gómez-Herrero, R., Grande, M., Heyner, D., Holmström, M., Huovelin, J., Kartavykh, Y., Laurenza, M., Lee, C. O., Mason, G., Maksimovic, M., Mieth, J., Murakami, G., Oleynik, P., Pinto, M., Pulupa, M., Richter, I., Rodríguez-Pacheco, J., Sánchez-Cano, B., Schuller, F., Ueno, H., Vainio, R., Vecchio, A., Veronig, A. M., and Wijsen, N.

Subjects
Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics
Abstract

Context. A solar eruption on 17 April 2021 produced a widespread Solar Energetic Particle (SEP) event that was observed by five longitudinally well-separated observers in the inner heliosphere at heliocentric distances of 0.42 to 1 au: BepiColombo, Parker Solar Probe, Solar Orbiter, STEREO A, and near-Earth spacecraft. The event produced relativistic electrons and protons. It was associated with a long-lasting solar hard X-ray flare and a medium fast Coronal Mass Ejection (CME) with a speed of 880 km/s driving a shock, an EUV wave as well as long-lasting radio burst activity showing four distinct type III burst. Methods. A multi-spacecraft analysis of remote-sensing and in-situ observations is applied to attribute the SEP observations at the different locations to the various potential source regions at the Sun. An ENLIL simulation is used to characterize the interplanetary state and its role for the energetic particle transport. The magnetic connection between each spacecraft and the Sun is determined. Based on a reconstruction of the coronal shock front we determine the times when the shock establishes magnetic connections with the different observers. Radio observations are used to characterize the directivity of the four main injection episodes, which are then employed in a 2D SEP transport simulation. Results. Timing analysis of the inferred SEP solar injection suggests different source processes being important for the electron and the proton event. Comparison among the characteristics and timing of the potential particle sources, such as the CME-driven shock or the flare, suggests a stronger shock contribution for the proton event and a more likely flare-related source of the electron event. Conclusions. We find that in this event an important ingredient for the wide SEP spread was the wide longitudinal range of about 110 degrees covered by distinct SEP injections.

Published
2023
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3. Investigating Mercury's Environment with the Two-Spacecraft BepiColombo Mission

Author

Milillo, A., Fujimoto, M., Murakami, G., Benkhoff, J., Zender, J., Aizawa, S., Dósa, M., Griton, L., Heyner, D., Ho, G., Imber, S. M., Jia, X., Karlsson, T., Killen, R. M., Laurenza, M., Lindsay, S. T., McKenna-Lawlor, S., Mura, A., Raines, J. M., Rothery, D. A., André, N., Baumjohann, W., Berezhnoy, A., Bourdin, P. -A., Bunce, E. J., Califano, F., Deca, J., de la Fuente, S., Dong, C., Grava, C., Fatemi, S., Henri, P., Ivanovski, S. L., Jackson, B. V., James, M., Kallio, E., Kasaba, Y., Kilpua, E., Kobayashi, M., Langlais, B., Leblanc, F., Lhotka, C., Mangano, V., Martindale, A., Massetti, S., Masters, A., Morooka, M., Narita, Y., Oliveira, J. S., Odstrcil, D., Orsini, S., Pelizzo, M. G., Plainaki, C., Plaschke, F., Sahraoui, F., Seki, K., Slavin, J. A., Vainio, R., Wurz, P., Barabash, S., Carr, C. M., Delcourt, D., Glassmeier, K. -H., Grande, M., Hirahara, M., Huovelin, J., Korablev, O., Kojima, H., Lichtenegger, H., Livi, S., Matsuoka, A., Moissl, R., Moncuquet, M., Muinonen, K., Quèmerais, E., Saito, Y., Yagitani, S., Yoshikawa, I., and Wahlund, J. -E.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics
Abstract

The ESA-JAXA BepiColombo mission will provide simultaneous measurements from two spacecraft, offering an unprecedented opportunity to investigate magnetospheric and exospheric dynamics at Mercury as well as their interactions with the solar wind, radiation, and interplanetary dust. Many scientific instruments onboard the two spacecraft will be completely, or partially devoted to study the near-space environment of Mercury as well as the complex processes that govern it. Many issues remain unsolved even after the MESSENGER mission that ended in 2015. The specific orbits of the two spacecraft, MPO and Mio, and the comprehensive scientific payload allow a wider range of scientific questions to be addressed than those that could be achieved by the individual instruments acting alone, or by previous missions. These joint observations are of key importance because many phenomena in Mercury's environment are highly temporally and spatially variable. Examples of possible coordinated observations are described in this article, analysing the required geometrical conditions, pointing, resolutions and operation timing of different BepiColombo instruments sensors., Comment: 78 pages, 14 figures, published

Published
2022
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4. Multi-spacecraft observations of the structure of the sheath of an interplanetary coronal mass ejection and related energetic ion enhancement

Author

Kilpua, E. K. J., Good, S. W., Dresing, N., Vainio, R., Davies, E. E., Forsyth, R. J., Gieseler, J., Lavraud, B., Asvestari, E., Morosan, D. E., Pomoell, J., Price, D. J., Heyner, D., Horbury, T. S., Angelini, V., O'Brien, H., Evans, V., Rodriguez-Pacheco, J., Herrero, R. Gómez, Ho, G. C., and Wimmer-Schweingruber, R.

Subjects
Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics, Physics - Plasma Physics
Abstract

Sheaths ahead of coronal mass ejections (CMEs) are large heliospheric structures that form with CME expansion and propagation. Turbulent and compressed sheaths contribute to the acceleration of particles in the corona and in interplanetary space, but the relation of their internal structures to particle energization is still relatively little studied. In particular, the role of sheaths in accelerating particles when the shock Mach number is low is a significant open problem. This work seeks to provide new insights on the internal structure of CME sheaths with regard to energetic particle enhancements. A good opportunity to achieve this aim was provided by observations of a sheath made by radially aligned spacecraft at 0.8 and $\sim$ 1 AU (Solar Orbiter, Wind, ACE and BepiColombo) on 19-21 April 2020. The sheath was preceded by a weak shock. Energetic ion enhancements occurred at different locations within the sheath structure at Solar Orbiter and L1. Magnetic fluctuation amplitudes at inertial-range scales increased in the sheath relative to the upstream wind. However, when normalised to the local mean field, fluctuation amplitudes did not increase significantly; magnetic compressibility of fluctuation also did not increase. Various substructures were embedded within the sheath at the different spacecraft, including multiple heliospheric current sheet (HCS) crossings and a small-scale flux rope. At L1, the ion flux enhancement was associated with the HCS crossings, while at Solar Orbiter, the enhancement occurred within the rope. Substructures that are swept from the upstream solar wind and compressed in the sheath can act as particularly effective acceleration sites. A possible acceleration mechanism is betatron acceleration associated with the small-scale flux rope and the warped HCS in the sheath., Comment: 14 pages, 12 figures; published in Astronomy & Astrophysics, Solar Orbiter First Results (Cruise Phase) special issue

Published
2021
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5. Multipoint interplanetary coronal mass ejections observed with Solar Orbiter, BepiColombo, Parker Solar Probe, Wind and STEREO-A

Author

Möstl, C., Weiss, A. J., Reiss, M. A., Amerstorfer, T., Bailey, R. L., Hinterreiter, J., Bauer, M., Barnes, D., Davies, J. A., Harrison, R. A., von Forstner, J. L. Freiherr, Davies, E. E., Heyner, D., Horbury, T., and Bale, S. D.

Subjects
Astrophysics - Solar and Stellar Astrophysics, Physics - Space Physics
Abstract

We report the result of the first search for multipoint in situ and imaging observations of interplanetary coronal mass ejections (ICMEs) starting with the first Solar Orbiter (SolO) data in 2020 April - 2021 April. A data exploration analysis is performed including visualizations of the magnetic field and plasma observations made by the five spacecraft SolO, BepiColombo, Parker Solar Probe (PSP), Wind and STEREO-A, in connection with coronagraph and heliospheric imaging observations from STEREO-A/SECCHI and SOHO/LASCO. We identify ICME events that could be unambiguously followed with the STEREO-A heliospheric imagers during their interplanetary propagation to their impact at the aforementioned spacecraft, and look for events where the same ICME is seen in situ by widely separated spacecraft. We highlight two events: (1) a small streamer blowout CME on 2020 June 23 observed with a triple lineup by PSP, BepiColombo and Wind, guided by imaging with STEREO-A, and (2) the first fast CME of solar cycle 25 ($ \approx 1600$ km s$^{-1}$) on 2020 November 29 observed in situ by PSP and STEREO-A. These results are useful for modeling the magnetic structure of ICMEs and the interplanetary evolution and global shape of their flux ropes and shocks, and for studying the propagation of solar energetic particles. The combined data from these missions are already turning out to be a treasure trove for space weather research and are expected to become even more valuable with an increasing number of ICME events expected during the rise and maximum of solar cycle 25., Comment: in press at ApJ Letters (submitted 2021 September 15, revised 2021 November 24, accepted 2021 December 9). 11 pages, 3 figures, 1 table

Published
2021
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6. Multi-spacecraft Study of the Solar Wind at Solar Minimum: Dependence on Latitude and Transient Outflows

Author

Laker, R., Horbury, T. S., Bale, S. D., Matteini, L., Woolley, T., Woodham, L. D., Stawarz, J. E., Davies, E. E., Eastwood, J. P., Owens, M. J., O'Brien, H., Evans, V., Angelini, V., Richter, I., Heyner, D., Owen, C. J., Louarn, P., and Federov, A.

Subjects
Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics
Abstract

The recent launches of Parker Solar Probe (PSP), Solar Orbiter (SO) and BepiColombo, along with several older spacecraft, have provided the opportunity to study the solar wind at multiple latitudes and distances from the Sun simultaneously. We take advantage of this unique spacecraft constellation, along with low solar activity across two solar rotations between May and July 2020, to investigate how the solar wind structure, including the Heliospheric Current Sheet (HCS), varies with latitude. We visualise the sector structure of the inner heliosphere by ballistically mapping the polarity and solar wind speed from several spacecraft onto the Sun's source surface. We then assess the HCS morphology and orientation with the in situ data and compare with a predicted HCS shape. We resolve ripples in the HCS on scales of a few degrees in longitude and latitude, finding that the local orientation of sector boundaries were broadly consistent with the shape of the HCS but were steepened with respect to a modelled HCS at the Sun. We investigate how several CIRs varied with latitude, finding evidence for the compression region affecting slow solar wind outside the latitude extent of the faster stream. We also identified several transient structures associated with HCS crossings, and speculate that one such transient may have disrupted the local HCS orientation up to five days after its passage. We have shown that the solar wind structure varies significantly with latitude, with this constellation providing context for solar wind measurements that would not be possible with a single spacecraft. These measurements provide an accurate representation of the solar wind within $\pm 10^{\circ}$ latitude, which could be used as a more rigorous constraint on solar wind models and space weather predictions. In the future, this range of latitudes will increase as SO's orbit becomes more inclined., Comment: Accepted version

Published
2021
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7. In situ multi-spacecraft and remote imaging observations of the first CME detected by Solar Orbiter and BepiColombo

Author

Davies, E. E., Möstl, C., Owens, M. J., Weiss, A. J., Amerstorfer, T., Hinterreiter, J., Bauer, M., Bailey, R. L., Reiss, M. A., Forsyth, R. J., Horbury, T. S., O'Brien, H., Evans, V., Angelini, V., Heyner, D., Richter, I., Auster, H-U., Magnes, W., Baumjohann, W., Fischer, D., Barnes, D., Davies, J. A., and Harrison, R. A.

Subjects
Physics - Space Physics, Astrophysics - Solar and Stellar Astrophysics
Abstract

On 2020 April 19 a coronal mass ejection (CME) was detected in situ by Solar Orbiter at a heliocentric distance of about 0.8 AU. The CME was later observed in situ on April 20th by the Wind and BepiColombo spacecraft whilst BepiColombo was located very close to Earth. This CME presents a good opportunity for a triple radial alignment study, as the spacecraft were separated by less than 5$^\circ$ in longitude. The source of the CME, which was launched on April 15th, was an almost entirely isolated streamer blowout. STEREO-A observed the event remotely from -75.1$^\circ$ longitude, which is an exceptionally well suited viewpoint for heliospheric imaging of an Earth directed CME. The configuration of the four spacecraft has provided an exceptionally clean link between remote imaging and in situ observations of the CME. We have used the in situ observations of the CME at Solar Orbiter, Wind, and BepiColombo, and the remote observations of the CME at STEREO-A in combination with flux rope models to determine the global shape of the CME and its evolution as it propagated through the inner heliosphere. A clear flattening of the CME cross-section has been observed by STEREO-A, and further confirmed by comparing profiles of the flux rope models to the in situ data, where the distorted flux rope cross-section qualitatively agrees most with in situ observations of the magnetic field at Solar Orbiter. Comparing in situ observations of the magnetic field between spacecraft, we find that the dependence of the maximum (mean) magnetic field strength decreases with heliocentric distance as $r^{-1.24 \pm 0.50}$ ($r^{-1.12 \pm 0.14}$), in disagreement with previous studies. Further assessment of the axial and poloidal magnetic field strength dependencies suggests that the expansion of the CME is likely neither self-similar nor cylindrically symmetric.

Published
2020
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8. LatHyS global hybrid simulation of the BepiColombo second Venus flyby

Author

Aizawa, S., Persson, M., Menez, T., André, N., Modolo, R., Génot, V., Sanchez-Cano, B., Volwerk, M., Chaufray, J.-Y., Baskevitch, C., Heyner, D., Saito, Y., Harada, Y., Leblanc, F., Barthe, A., Penou, E., Fedorov, A., Sauvaud, J.-A., Yokota, S., Auster, U., Richter, I., Mieth, J., Horbury, T.S., Louarn, P., Owen, C.J., and Murakami, G.

Published
2022
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9. BepiColombo mission confirms stagnation region of Venus and reveals its large extent

Author

Persson, M., Aizawa, S., André, N., Barabash, S., Saito, Y., Harada, Y., Heyner, D., Orsini, S., Fedorov, A., Mazelle, C., Futaana, Y., Hadid, L. Z., Volwerk, M., Collinson, G., Sanchez-Cano, B., Barthe, A., Penou, E., Yokota, S., Génot, V., Sauvaud, J. A., Delcourt, D., Fraenz, M., Modolo, R., Milillo, A., Auster, H.-U., Richter, I., Mieth, J. Z. D., Louarn, P., Owen, C. J., Horbury, T. S., Asamura, K., Matsuda, S., Nilsson, H., Wieser, M., Alberti, T., Varsani, A., Mangano, V., Mura, A., Lichtenegger, H., Laky, G., Jeszenszky, H., Masunaga, K., Signoles, C., Rojo, M., and Murakami, G.

Published
2022
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11. Multispacecraft Observations of a Widespread Solar Energetic Particle Event on 2022 February 15–16

Author

Khoo, L. Y., primary, Sánchez-Cano, B., additional, Lee, C. O., additional, Rodríguez-García, L., additional, Kouloumvakos, A., additional, Palmerio, E., additional, Carcaboso, F., additional, Lario, D., additional, Dresing, N., additional, Cohen, C. M. S., additional, McComas, D. J., additional, Lynch, B. J., additional, Fraschetti, F., additional, Jebaraj, I. C., additional, Mitchell, J. G., additional, Nieves-Chinchilla, T., additional, Krupar, V., additional, Pacheco, D., additional, Giacalone, J., additional, Auster, H.-U., additional, Benkhoff, J., additional, Bonnin, X., additional, Christian, E. R., additional, Ehresmann, B., additional, Fedeli, A., additional, Fischer, D., additional, Heyner, D., additional, Holmström, M., additional, Leske, R. A., additional, Maksimovic, M., additional, Mieth, J. Z. D., additional, Oleynik, P., additional, Pinto, M., additional, Richter, I., additional, Rodríguez-Pacheco, J., additional, Schwadron, N. A., additional, Schmid, D., additional, Telloni, D., additional, Vecchio, A., additional, and Wiedenbeck, M. E., additional

Published
2024
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14. Electron moments derived from the Mercury Electron Analyzer during the cruise phase of BepiColombo

Author

Rojo, M., Persson, M., Sauvaud, J. -a., Aizawa, S., Nicolaou, G., Penou, E., Barthe, A., Andre, N., Mazelle, C., Fedorov, A., Yokota, S., Saito, Y., Heyner, D., Richter, I., Auster, U., Schmid, D., Fischer, D., Horbury, T., Owen, C. J., Maksimovic, M., Khotyaintsev, Yuri V., Louarn, P., Murakami, G., Rojo, M., Persson, M., Sauvaud, J. -a., Aizawa, S., Nicolaou, G., Penou, E., Barthe, A., Andre, N., Mazelle, C., Fedorov, A., Yokota, S., Saito, Y., Heyner, D., Richter, I., Auster, U., Schmid, D., Fischer, D., Horbury, T., Owen, C. J., Maksimovic, M., Khotyaintsev, Yuri V., Louarn, P., and Murakami, G.

Abstract

Aims. We derive electron density and temperature from observations obtained by the Mercury Electron Analyzer on board Mio during the cruise phase of BepiColombo while the spacecraft is in a stacked configuration. Methods. In order to remove the secondary electron emission contribution, we first fit the core electron population of the solar wind with a Maxwellian distribution. We then subtract the resulting distribution from the complete electron spectrum, and suppress the residual count rates observed at low energies. Hence, our corrected count rates consist of the sum of the fitted Maxwellian core electron population with a contribution at higher energies. We finally estimate the electron density and temperature from the corrected count rates using a classical integration method. We illustrate the results of our derivation for two case studies, including the second Venus flyby of BepiColombo when the Solar Orbiter spacecraft was located nearby, and for a statistical study using observations obtained to date for distances to the Sun ranging from 0.3 to 0.9 AU. Results. When compared either to measurements of Solar Orbiter or to measurements obtained by HELIOS and Parker Solar Probe, our method leads to a good estimation of the electron density and temperature. Hence, despite the strong limitations arising from the stacked configuration of BepiColombo during its cruise phase, we illustrate how we can retrieve reasonable estimates for the electron density and temperature for timescales from days down to several seconds.

Published
2024
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15. Electron moments derived from the Mercury Electron Analyzer during the cruise phase of BepiColombo

Author

Rojo, M., primary, Persson, M., additional, Sauvaud, J.-A., additional, Aizawa, S., additional, Nicolaou, G., additional, Penou, E., additional, Barthe, A., additional, André, N., additional, Mazelle, C., additional, Fedorov, A., additional, Yokota, S., additional, Saito, Y., additional, Heyner, D., additional, Richter, I., additional, Auster, U., additional, Schmid, D., additional, Fischer, D., additional, Horbury, T., additional, Owen, C.J., additional, Maksimovic, M., additional, Khotyaintsev, Y., additional, Louarn, P., additional, and Murakami, G., additional

Published
2023
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17. BepiColombo - Mission Overview and Science Goals

Author

Benkhoff, J., Murakami, G., Baumjohann, W., Besse, S., Bunce, E., Casale, M., Cremosese, G., Glassmeier, K.-H., Hayakawa, H., Heyner, D., Hiesinger, H., Huovelin, J., Hussmann, H., Iafolla, V., Iess, L., Kasaba, Y., Kobayashi, M., Milillo, A., Mitrofanov, I. G., Montagnon, E., Novara, M., Orsini, S., Quemerais, E., Reininghaus, U., Saito, Y., Santoli, F., Stramaccioni, D., Sutherland, O., Thomas, N., Yoshikawa, I., and Zender, J.

Published
2021
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20. The initial temporal evolution of a feedback dynamo for Mercury

Author

Heyner, D., Schmitt, D., Wicht, J., Glassmeier, K. -H., Korth, H., and Motschmann, U.

Subjects
Astrophysics - Earth and Planetary Astrophysics, Physics - Geophysics, Physics - Space Physics
Abstract

Various possibilities are currently under discussion to explain the observed weakness of the intrinsic magnetic field of planet Mercury. One of the possible dynamo scenarios is a dynamo with feedback from the magnetosphere. Due to its weak magnetic field Mercury exhibits a small magnetosphere whose subsolar magnetopause distance is only about 1.7 Hermean radii. We consider the magnetic field due to magnetopause currents in the dynamo region. Since the external field of magnetospheric origin is antiparallel to the dipole component of the dynamo field, a negative feedback results. For an alpha-omega-dynamo two stationary solutions of such a feedback dynamo emerge, one with a weak and the other with a strong magnetic field. The question, however, is how these solutions can be realized. To address this problem, we discuss various scenarios for a simple dynamo model and the conditions under which a steady weak magnetic field can be reached. We find that the feedback mechanism quenches the overall field to a low value of about 100 to 150 nT if the dynamo is not driven too strongly.

Published
2010
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21. The BepiColombo Planetary Magnetometer MPO-MAG: What Can We Learn from the Hermean Magnetic Field?

Author

Heyner, D., Auster, H.-U., Fornaçon, K.-H., Carr, C., Richter, I., Mieth, J. Z. D., Kolhey, P., Exner, W., Motschmann, U., Baumjohann, W., Matsuoka, A., Magnes, W., Berghofer, G., Fischer, D., Plaschke, F., Nakamura, R., Narita, Y., Delva, M., Volwerk, M., Balogh, A., Dougherty, M., Horbury, T., Langlais, B., Mandea, M., Masters, A., Oliveira, J. S., Sánchez-Cano, B., Slavin, J. A., Vennerstrøm, S., Vogt, J., Wicht, J., and Glassmeier, K.-H.

Published
2021
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22. Revised Magnetospheric Model Reveals Signatures of Field‐Aligned Current Systems at Mercury.

Author

Pump, K., Heyner, D., Schmid, D., Exner, W., and Plaschke, Ferdinand

Subjects
INTERPLANETARY magnetic fields, MERCURY, MERCURY (Planet), CURRENT sheets, SOLAR wind, MAGNETIC fields, STELLAR magnetic fields
Abstract

Mercury is the smallest and innermost planet of our solar system and has a dipole‐dominated internal magnetic field that is relatively weak, very axisymmetric and significantly offset toward north. Through the interaction with the solar wind, a magnetosphere is created. Compared to the magnetosphere of Earth, Mercury's magnetosphere is smaller and more dynamic. To understand the magnetospheric structures and processes we use in situ MESSENGER data to develop further a semi‐empiric model of the magnetospheric magnetic field, which can explain the observations and help to improve the mission planning for the BepiColombo mission en‐route to Mercury. We present this semi‐empiric KTH22‐model, a modular model to calculate the magnetic field inside the Hermean magnetosphere. Korth et al. (2015, https://doi.org/10.1002/2015JA021022, 2017, https://doi.org/10.1002/2017gl074699) published a model, which is the basis for the KTH22‐model. In this new version, the representation of the neutral sheet current magnetic field is more realistic, because it is now based on observations rather than ad‐hoc assumptions. Furthermore, a new module is added to depict the eastward ring shaped current magnetic field. These enhancements offer the possibility to improve the main field determination. In addition, analyzing the magnetic field residuals allows us to investigate the field‐aligned currents and their possible dependencies on external drivers. We see increasing currents under more disturbed conditions inside the magnetosphere, but no clear dependence on the z‐component of the interplanetary magnetic field nor on the magnetosheath plasma β. Key Points: We present a revised model of Mercury's magnetospheric magnetic fieldThe model now includes an eastward ring shaped current and the neutral sheet current is calculated more precisely with Biot Savart's lawThe strength of the field‐aligned currents increases with higher magnetic activity [ABSTRACT FROM AUTHOR]

Published
2024
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24. The BepiColombo–Mio Magnetometer en Route to Mercury

Author

Baumjohann, W., Matsuoka, A., Narita, Y., Magnes, W., Heyner, D., Glassmeier, K.-H., Nakamura, R., Fischer, D., Plaschke, F., Volwerk, M., Zhang, T. L., Auster, H.-U., Richter, I., Balogh, A., Carr, C. M., Dougherty, M., Horbury, T. S., Tsunakawa, H., Matsushima, M., Shinohara, M., Shibuya, H., Nakagawa, T., Hoshino, M., Tanaka, Y., Anderson, B. J., Russell, C. T., Motschmann, U., Takahashi, F., and Fujimoto, A.

Published
2020
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25. Magnetic holes between Earth and Mercury: BepiColombo cruise phase

Author

Volwerk, M., primary, Karlsson, T., additional, Heyner, D., additional, Goetz, C., additional, Simon Wedlund, C., additional, Plaschke, F., additional, Schmid, D., additional, Fischer, D., additional, Mieth, J., additional, Richter, I., additional, Nakamura, R., additional, Narita, Y., additional, Magnes, W., additional, Auster, U., additional, Matsuoka, A., additional, Baumjohann, W., additional, and Glassmeier, K.-H., additional

Published
2023
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26. The 17 April 2021 widespread solar energetic particle event

Author

Dresing, N., primary, Rodríguez-García, L., additional, Jebaraj, I. C., additional, Warmuth, A., additional, Wallace, S., additional, Balmaceda, L., additional, Podladchikova, T., additional, Strauss, R. D., additional, Kouloumvakos, A., additional, Palmroos, C., additional, Krupar, V., additional, Gieseler, J., additional, Xu, Z., additional, Mitchell, J. G., additional, Cohen, C. M. S., additional, de Nolfo, G. A., additional, Palmerio, E., additional, Carcaboso, F., additional, Kilpua, E. K. J., additional, Trotta, D., additional, Auster, U., additional, Asvestari, E., additional, da Silva, D., additional, Dröge, W., additional, Getachew, T., additional, Gómez-Herrero, R., additional, Grande, M., additional, Heyner, D., additional, Holmström, M., additional, Huovelin, J., additional, Kartavykh, Y., additional, Laurenza, M., additional, Lee, C. O., additional, Mason, G., additional, Maksimovic, M., additional, Mieth, J., additional, Murakami, G., additional, Oleynik, P., additional, Pinto, M., additional, Pulupa, M., additional, Richter, I., additional, Rodríguez-Pacheco, J., additional, Sánchez-Cano, B., additional, Schuller, F., additional, Ueno, H., additional, Vainio, R., additional, Vecchio, A., additional, Veronig, A. M., additional, and Wijsen, N., additional

Published
2023
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27. Investigating Mercury’s Environment with the Two-Spacecraft BepiColombo Mission

Author

Milillo, A., Fujimoto, M., Murakami, G., Benkhoff, J., Zender, J., Aizawa, S., Dósa, M., Griton, L., Heyner, D., Ho, G., Imber, S. M., Jia, X., Karlsson, T., Killen, R. M., Laurenza, M., Lindsay, S. T., McKenna-Lawlor, S., Mura, A., Raines, J. M., Rothery, D. A., André, N., Baumjohann, W., Berezhnoy, A., Bourdin, P. A., Bunce, E. J., Califano, F., Deca, J., de la Fuente, S., Dong, C., Grava, C., Fatemi, S., Henri, P., Ivanovski, S. L., Jackson, B. V., James, M., Kallio, E., Kasaba, Y., Kilpua, E., Kobayashi, M., Langlais, B., Leblanc, F., Lhotka, C., Mangano, V., Martindale, A., Massetti, S., Masters, A., Morooka, M., Narita, Y., Oliveira, J. S., Odstrcil, D., Orsini, S., Pelizzo, M. G., Plainaki, C., Plaschke, F., Sahraoui, F., Seki, K., Slavin, J. A., Vainio, R., Wurz, P., Barabash, S., Carr, C. M., Delcourt, D., Glassmeier, K.-H., Grande, M., Hirahara, M., Huovelin, J., Korablev, O., Kojima, H., Lichtenegger, H., Livi, S., Matsuoka, A., Moissl, R., Moncuquet, M., Muinonen, K., Quèmerais, E., Saito, Y., Yagitani, S., Yoshikawa, I., and Wahlund, J.-E.

Published
2020
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28. Magnetic holes between Earth and Mercury : BepiColombo cruise phase

Author

Volwerk, M., Karlsson, Tomas, Heyner, D., Goetz, C., Simon Wedlund, C., Plaschke, F., Schmid, D., Fischer, D., Mieth, J., Richter, I., Nakamura, R., Narita, Y., Magnes, W., Auster, U., Matsuoka, A., Baumjohann, W., Glassmeier, K. -H, Volwerk, M., Karlsson, Tomas, Heyner, D., Goetz, C., Simon Wedlund, C., Plaschke, F., Schmid, D., Fischer, D., Mieth, J., Richter, I., Nakamura, R., Narita, Y., Magnes, W., Auster, U., Matsuoka, A., Baumjohann, W., and Glassmeier, K. -H

Abstract

Context. Magnetic holes are ubiquitous structures in the solar wind and in planetary magnetosheaths. They consist of a strong depression of the magnetic field strength, most likely in pressure balance through increased plasma pressure, which is convected with the plasma flow. These structures are created through a plasma temperature anisotropy, where the perpendicular temperature (with respect to the magnetic field) is greater than the parallel temperature. The occurrence rate of these magnetic holes between Earth and Mercury can give us information about how the solar wind conditions develop on their way from the Sun to the outer Solar System. They also give information about basic plasma processes such as diffusion of magnetic structures.Aims. In this study we investigate the occurrence, size, and depth of magnetic holes during the cruise phase of BepiColombo and compare them with earlier studies.Methods. The BepiColombo magnetometer data were used to find the magnetic holes. We determined the size in seconds, the depth with respect to the background field, and the rotation angle of the background field across the structure. Minimum variance analysis delivers the polarization state of the magnetic holes. A direct comparison is made to the results obtained from the MESSENGER cruise phase.Results. We find an almost constant occurrence rate for magnetic holes between Mercury and Earth. The size of the holes is determined by the plasma conditions at the location where they are created and they grow in size, due to diffusion, as they move outwards in the Solar System. The greater the rotation of the background magnetic field across the structure, the larger the minimum size of the magnetic hole is., QC 20230922

Published
2023
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30. High-energy particle enhancements in the solar wind upstream Mercury during the first BepiColombo flyby: SERENA/PICAM and MPO-MAG observations

Author

Alberti, T., primary, Sun, W., additional, Varsani, A., additional, Heyner, D., additional, Orsini, S., additional, Milillo, A., additional, Slavin, J. A., additional, Raines, J. M., additional, Aronica, A., additional, Auster, H.-U., additional, Barabash, S., additional, De Angelis, E., additional, Dandouras, I., additional, Jarvinen, R., additional, Jeszenszky, H., additional, Kallio, E., additional, Kazakov, A., additional, Laky, G., additional, Livi, S., additional, Mangano, V., additional, Massetti, S., additional, Moroni, M., additional, Mura, A., additional, Noschese, R., additional, Plainaki, C., additional, Plaschke, F., additional, Richter, I., additional, Rispoli, R., additional, Sordini, R., additional, and Wurz, P., additional

Published
2023
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33. Influence of Large-scale Interplanetary Structures on the Propagation of Solar Energetic Particles: The Multispacecraft Event on 2021 October 9

Author

Lario, D., primary, Wijsen, N., additional, Kwon, R. Y., additional, Sánchez-Cano, B., additional, Richardson, I. G., additional, Pacheco, D., additional, Palmerio, E., additional, Stevens, M. L., additional, Szabo, A., additional, Heyner, D., additional, Dresing, N., additional, Gómez-Herrero, R., additional, Carcaboso, F., additional, Aran, A., additional, Afanasiev, A., additional, Vainio, R., additional, Riihonen, E., additional, Poedts, S., additional, Brüden, M., additional, Xu, Z. G., additional, and Kollhoff, A., additional

Published
2022
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34. Young or not so young? Constraining the thermal evolution of the Moon with a landed mission to Ina-D

Author

Hauber, Ernst, Auster, H-U., Biele, Jens, Brož, Petr, Grott, Matthias, Heyner, D., Hübers, Heinz-Wilhelm, Karatekin, O, Lichtenheldt, Roy, Ritter, B., Schmitz, Nicole, Schröder, Susanne, Ulamec, Stephan, Wedler, Armin, De Sanctis, C.M., Besse, S., Hiesinger, H., Frigeri, A., Crawford, I.A., Tartese, R., Ciarletti, V., Massironi, M, Rull, F., Ehlmann, B, Klima, R. L., Head, J W, Wilson, L., Qiao, L., McDonald, Francesca, and Carpenter, J.

Subjects
volcanism, geology, Argonaut, EL3, Moon, exploration, lander
Published
2022

35. Multi-point analysis of coronal mass ejection flux ropes using combined data from Solar Orbiter, BepiColombo, and Wind

Author

Weiss, A. J., primary, Möstl, C., additional, Davies, E. E., additional, Amerstorfer, T., additional, Bauer, M., additional, Hinterreiter, J., additional, Reiss, M. A., additional, Bailey, R. L., additional, Horbury, T. S., additional, O’Brien, H., additional, Evans, V., additional, Angelini, V., additional, Heyner, D., additional, Richter, I., additional, Auster, H.-U., additional, Magnes, W., additional, Fischer, D., additional, and Baumjohann, W., additional

Published
2021
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36. Multi-spacecraft observations of the structure of the sheath of an interplanetary coronal mass ejection and related energetic ion enhancement

Author

Kilpua, E. K. J., primary, Good, S. W., additional, Dresing, N., additional, Vainio, R., additional, Davies, E. E., additional, Forsyth, R. J., additional, Gieseler, J., additional, Lavraud, B., additional, Asvestari, E., additional, Morosan, D. E., additional, Pomoell, J., additional, Price, D. J., additional, Heyner, D., additional, Horbury, T. S., additional, Angelini, V., additional, O’Brien, H., additional, Evans, V., additional, Rodriguez-Pacheco, J., additional, Gómez Herrero, R., additional, Ho, G. C., additional, and Wimmer-Schweingruber, R., additional

Published
2021
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37. In situ multi-spacecraft and remote imaging observations of the first CME detected by Solar Orbiter and BepiColombo

Author

Davies, E. E., primary, Möstl, C., additional, Owens, M. J., additional, Weiss, A. J., additional, Amerstorfer, T., additional, Hinterreiter, J., additional, Bauer, M., additional, Bailey, R. L., additional, Reiss, M. A., additional, Forsyth, R. J., additional, Horbury, T. S., additional, O’Brien, H., additional, Evans, V., additional, Angelini, V., additional, Heyner, D., additional, Richter, I., additional, Auster, H.-U., additional, Magnes, W., additional, Baumjohann, W., additional, Fischer, D., additional, Barnes, D., additional, Davies, J. A., additional, and Harrison, R. A., additional

Published
2021
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38. The fluxgate magnetometer of the BepiColombo Mercury Planetary Orbiter

Author

Glassmeier, K.-H., Auster, H.-U., Heyner, D., Okrafka, K., Carr, C., Berghofer, G., Anderson, B.J., Balogh, A., Baumjohann, W., Cargill, P., Christensen, U., Delva, M., Dougherty, M., Fornaçon, K.-H., Horbury, T.S., Lucek, E.A., Magnes, W., Mandea, M., Matsuoka, A., Matsushima, M., Motschmann, U., Nakamura, R., Narita, Y., O’Brien, H., Richter, I., Schwingenschuh, K., Shibuya, H., Slavin, J.A., Sotin, C., Stoll, B., Tsunakawa, H., Vennerstrom, S., Vogt, J., and Zhang, T.

Published
2010
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40. Multi-spacecraft study of the solar wind at solar minimum: Dependence on latitude and transient outflows

Author

Laker, R., primary, Horbury, T. S., additional, Bale, S. D., additional, Matteini, L., additional, Woolley, T., additional, Woodham, L. D., additional, Stawarz, J. E., additional, Davies, E. E., additional, Eastwood, J. P., additional, Owens, M. J., additional, O’Brien, H., additional, Evans, V., additional, Angelini, V., additional, Richter, I., additional, Heyner, D., additional, Owen, C. J., additional, Louarn, P., additional, and Fedorov, A., additional

Published
2021
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42. 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
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48. Investigating Mercury’s Environment with the Two-Spacecraft BepiColombo Mission

Author

Milillo, A., Fujimoto, M., Murakami, G., Benkhoff, J., Zender, J., Aizawa, S., Dósa, M., Griton, L., Heyner, D., Ho, G., Imber, S. M., Jia, X., Karlsson, T., Killen, R. M., Laurenza, M., Lindsay, S. T., McKenna-Lawlor, S., Mura, A., Raines, J. M., Rothery, D. A., André, N., Baumjohann, W., Berezhnoy, A., Bourdin, P. A., Bunce, E. J., Califano, F., Deca, J., de la Fuente, S., Dong, C., Grava, C., Fatemi, S., Henri, P., Ivanovski, S. L., Jackson, B. V., James, M., Kallio, E., Kasaba, Y., Kilpua, E., Kobayashi, M., Langlais, B., Leblanc, F., Lhotka, C., Mangano, V., Martindale, A., Massetti, S., Masters, A., Morooka, M., Narita, Y., Oliveira, J. S., Odstrcil, D., Orsini, S., Pelizzo, M. G., Plainaki, C., Plaschke, F., Sahraoui, F., Seki, K., Slavin, J. A., Vainio, R., Wurz, P., Barabash, S., Carr, C. M., Delcourt, D., Glassmeier, K.-H., Grande, M., Hirahara, M., Huovelin, J., Korablev, O., Kojima, H., Lichtenegger, H., Livi, S., Matsuoka, A., Moissl, R., Moncuquet, M., Muinonen, K., Quèmerais, E., Saito, Y., Yagitani, S., Yoshikawa, I., Wahlund, J.-E., Milillo, A., Fujimoto, M., Murakami, G., Benkhoff, J., Zender, J., Aizawa, S., Dósa, M., Griton, L., Heyner, D., Ho, G., Imber, S. M., Jia, X., Karlsson, T., Killen, R. M., Laurenza, M., Lindsay, S. T., McKenna-Lawlor, S., Mura, A., Raines, J. M., Rothery, D. A., André, N., Baumjohann, W., Berezhnoy, A., Bourdin, P. A., Bunce, E. J., Califano, F., Deca, J., de la Fuente, S., Dong, C., Grava, C., Fatemi, S., Henri, P., Ivanovski, S. L., Jackson, B. V., James, M., Kallio, E., Kasaba, Y., Kilpua, E., Kobayashi, M., Langlais, B., Leblanc, F., Lhotka, C., Mangano, V., Martindale, A., Massetti, S., Masters, A., Morooka, M., Narita, Y., Oliveira, J. S., Odstrcil, D., Orsini, S., Pelizzo, M. G., Plainaki, C., Plaschke, F., Sahraoui, F., Seki, K., Slavin, J. A., Vainio, R., Wurz, P., Barabash, S., Carr, C. M., Delcourt, D., Glassmeier, K.-H., Grande, M., Hirahara, M., Huovelin, J., Korablev, O., Kojima, H., Lichtenegger, H., Livi, S., Matsuoka, A., Moissl, R., Moncuquet, M., Muinonen, K., Quèmerais, E., Saito, Y., Yagitani, S., Yoshikawa, I., and Wahlund, J.-E.

Abstract

The ESA-JAXA BepiColombo mission will provide simultaneous measurements from two spacecraft, offering an unprecedented opportunity to investigate magnetospheric and exospheric dynamics at Mercury as well as their interactions with the solar wind, radiation, and interplanetary dust. Many scientific instruments onboard the two spacecraft will be completely, or partially devoted to study the near-space environment of Mercury as well as the complex processes that govern it. Many issues remain unsolved even after the MESSENGER mission that ended in 2015. The specific orbits of the two spacecraft, MPO and Mio, and the comprehensive scientific payload allow a wider range of scientific questions to be addressed than those that could be achieved by the individual instruments acting alone, or by previous missions. These joint observations are of key importance because many phenomena in Mercury’s environment are highly temporally and spatially variable. Examples of possible coordinated observations are described in this article, analysing the required geometrical conditions, pointing, resolutions and operation timing of different BepiColombo instruments sensors.

49. Investigating Mercury’s Environment with the Two-Spacecraft BepiColombo Mission

Author

Milillo, A., Fujimoto, M., Murakami, G., Benkhoff, J., Zender, J., Aizawa, S., Dósa, M., Griton, L., Heyner, D., Ho, G., Imber, S. M., Jia, X., Karlsson, T., Killen, R. M., Laurenza, M., Lindsay, S. T., McKenna-Lawlor, S., Mura, A., Raines, J. M., Rothery, D. A., André, N., Baumjohann, W., Berezhnoy, A., Bourdin, P. A., Bunce, E. J., Califano, F., Deca, J., de la Fuente, S., Dong, C., Grava, C., Fatemi, S., Henri, P., Ivanovski, S. L., Jackson, B. V., James, M., Kallio, E., Kasaba, Y., Kilpua, E., Kobayashi, M., Langlais, B., Leblanc, F., Lhotka, C., Mangano, V., Martindale, A., Massetti, S., Masters, A., Morooka, M., Narita, Y., Oliveira, J. S., Odstrcil, D., Orsini, S., Pelizzo, M. G., Plainaki, C., Plaschke, F., Sahraoui, F., Seki, K., Slavin, J. A., Vainio, R., Wurz, P., Barabash, S., Carr, C. M., Delcourt, D., Glassmeier, K.-H., Grande, M., Hirahara, M., Huovelin, J., Korablev, O., Kojima, H., Lichtenegger, H., Livi, S., Matsuoka, A., Moissl, R., Moncuquet, M., Muinonen, K., Quèmerais, E., Saito, Y., Yagitani, S., Yoshikawa, I., Wahlund, J.-E., Milillo, A., Fujimoto, M., Murakami, G., Benkhoff, J., Zender, J., Aizawa, S., Dósa, M., Griton, L., Heyner, D., Ho, G., Imber, S. M., Jia, X., Karlsson, T., Killen, R. M., Laurenza, M., Lindsay, S. T., McKenna-Lawlor, S., Mura, A., Raines, J. M., Rothery, D. A., André, N., Baumjohann, W., Berezhnoy, A., Bourdin, P. A., Bunce, E. J., Califano, F., Deca, J., de la Fuente, S., Dong, C., Grava, C., Fatemi, S., Henri, P., Ivanovski, S. L., Jackson, B. V., James, M., Kallio, E., Kasaba, Y., Kilpua, E., Kobayashi, M., Langlais, B., Leblanc, F., Lhotka, C., Mangano, V., Martindale, A., Massetti, S., Masters, A., Morooka, M., Narita, Y., Oliveira, J. S., Odstrcil, D., Orsini, S., Pelizzo, M. G., Plainaki, C., Plaschke, F., Sahraoui, F., Seki, K., Slavin, J. A., Vainio, R., Wurz, P., Barabash, S., Carr, C. M., Delcourt, D., Glassmeier, K.-H., Grande, M., Hirahara, M., Huovelin, J., Korablev, O., Kojima, H., Lichtenegger, H., Livi, S., Matsuoka, A., Moissl, R., Moncuquet, M., Muinonen, K., Quèmerais, E., Saito, Y., Yagitani, S., Yoshikawa, I., and Wahlund, J.-E.

Abstract

The ESA-JAXA BepiColombo mission will provide simultaneous measurements from two spacecraft, offering an unprecedented opportunity to investigate magnetospheric and exospheric dynamics at Mercury as well as their interactions with the solar wind, radiation, and interplanetary dust. Many scientific instruments onboard the two spacecraft will be completely, or partially devoted to study the near-space environment of Mercury as well as the complex processes that govern it. Many issues remain unsolved even after the MESSENGER mission that ended in 2015. The specific orbits of the two spacecraft, MPO and Mio, and the comprehensive scientific payload allow a wider range of scientific questions to be addressed than those that could be achieved by the individual instruments acting alone, or by previous missions. These joint observations are of key importance because many phenomena in Mercury’s environment are highly temporally and spatially variable. Examples of possible coordinated observations are described in this article, analysing the required geometrical conditions, pointing, resolutions and operation timing of different BepiColombo instruments sensors.

50. Geodesy, Geophysics and Fundamental Physics Investigations of the BepiColombo Mission

Author

Nicola Tosi, Paolo Cappuccio, Francesco Santoli, Tim Van Hoolst, J. S. Oliveira, Daniel Heyner, Nicolas Thomas, Alexander Stark, Johannes Wicht, Luciano Iess, H. Hussmann, Ivan di Stefano, Antonio Genova, Johannes Benkhoff, Patrick Kolhey, Johannes Z. D. Mieth, Gregor Steinbrügge, Benoit Langlais, Genova, A. [0000-0001-5584-492X], Hussmann, H. [0000-0002-3816-0232], Van Hoolst, T. [0000-0002-9820-8584], Heyner, D. [0000-0001-7894-8246], Iess, L. [0000-0002-6230-5825], Santoli, F. [0000-0003-2493-0109], Thomas, N. [0000-0002-0146-0071], Cappuccio, P. [0000-0002-8758-6627], Di Stefano, I. [0000-0003-1491-6848], Langlais, B. [0000-0001-5207-304X], Oliveira, J. S. [0000-0002-4587-2895], Stark, A. [0000-0001-9110-1138], Steinbrügge, G. [0000-0002-1050-7759], Tosi, N. [0000-0002-4912-2848], Wicht, J. [0000-0002-2440-5091], Benkhoff, J. [0000-0002-4307-9703], Agenzia Spaziale Italiana (ASI), Bundesministerium für Wirtschaft und Energie (BMWi), Deutsches Zentrum für Luft- und Raumfahrt (DLR), Laboratoire de Planétologie et Géodynamique [UMR 6112] (LPG), Université d'Angers (UA)-Université de Nantes - UFR des Sciences et des Techniques (UN UFR ST), and Université de Nantes (UN)-Université de Nantes (UN)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)

Subjects
Solar System, Engineering, Topography, 010504 meteorology & atmospheric sciences, BepiColombo, Gravity, [SDU.ASTR.EP]Sciences of the Universe [physics]/Astrophysics [astro-ph]/Earth and Planetary Astrophysics [astro-ph.EP], chemistry.chemical_element, Astronomy & Astrophysics, 01 natural sciences, law.invention, Orbiter, Theories of gravitation, Planetenphysik, Planet, law, 0103 physical sciences, Altimeter, Internal structure, 010303 astronomy & astrophysics, 0105 earth and related environmental sciences, Radio Science, Science & Technology, Spacecraft, business.industry, 520 Astronomy, Planetengeodäsie, Astronomy and Astrophysics, Geophysics, Mercury, Geodesy, 620 Engineering, Mercury (element), Planetary science, Magnetic field, chemistry, 13. Climate action, Space and Planetary Science, gravity, internal structure, magnetic field, theories of gravitation, thermal evolution, topography, Physical Sciences, business, Thermal evolution
Abstract

Open access funding provided by Università degli Studi di Roma La Sapienza within the CRUI-CARE Agreement. In preparation for the ESA/JAXA BepiColombo mission to Mercury, thematic working groups had been established for coordinating the activities within the BepiColombo Science Working Team in specific fields. Here we describe the scientific goals of the Geodesy and Geophysics Working Group (GGWG) that aims at addressing fundamental questions regarding Mercury’s internal structure and evolution. This multidisciplinary investigation will also test the gravity laws by using the planet Mercury as a proof mass. The instruments on the Mercury Planetary Orbiter (MPO), which are devoted to accomplishing the GGWG science objectives, include the BepiColombo Laser Altimeter (BELA), the Mercury orbiter radio science experiment (MORE), and the MPO magnetometer (MPO-MAG). The onboard Italian spring accelerometer (ISA) will greatly aid the orbit reconstruction needed by the gravity investigation and laser altimetry. We report the current knowledge on the geophysics, geodesy, and evolution of Mercury after the successful NASA mission MESSENGER and set the prospects for the BepiColombo science investigations based on the latest findings on Mercury’s interior. The MPO spacecraft of the BepiColombo mission will provide extremely accurate measurements of Mercury’s topography, gravity, and magnetic field, extending and improving MESSENGER data coverage, in particular in the southern hemisphere. Furthermore, the dual-spacecraft configuration of the BepiColombo mission with the Mio spacecraft at higher altitudes than the MPO spacecraft will be fundamental for decoupling the internal and external contributions of Mercury’s magnetic field. Thanks to the synergy between the geophysical instrument suite and to the complementary instruments dedicated to the investigations on Mercury’s surface, composition, and environment, the BepiColombo mission is poised to advance our understanding of the interior and evolution of the innermost planet of the solar system. We are grateful to the ESA spacecraft operations team for supporting and planning the scientific observations during BepiColombo cruise and orbital mission. A.G. and L.I. thank A. Di Ruscio (Sapienza University of Rome) for his support in the numerical simulations of the MORE investigation. A.G. and L.I. acknowledge funding from the Italian Space Agency (ASI) grant N. 2017-40-H.0. T.V.H. was financially supported by the Belgian Research Action through Interdisciplinary Networks (BRAIN.be 2.0 project STEM) and by the Belgian PRODEX program managed by the European Space Agency in collaboration with the Belgian Federal Science Policy Office. D.H. was financially supported by the German Ministerium für Wirtschaft und Energie and the German Zentrum für Luft- und Raumfahrt under contract 50 QW 1501. F.S. was financially supported by ASI through the cooperation agreement N. 2017-47-H.0. We acknowledge Gregory A. Neumann and an anonymous referee for their helpful comments to improve the quality of this paper. The data used in this study for the numerical simulations of the BepiColombo mission are available at https://www.cosmos.esa.int/web/spice/spice-for-bepicolombo. Peerreview

Published
2021

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