Development of a cometosheath at comet 67P/Churyumov-Gerasimenko: A case study comparison of Rosetta observations

Context. The ionosphere of a comet is known to deflect the solar wind through mass loading, but the interaction is dependent on cometary activity. We investigate the details of this process at comet 67P using the Rosetta Ion Composition Analyzer. Aims. This study aims to compare the interaction of t...

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Bibliographic Details
Published in:Astronomy and astrophysics (Berlin) 2022-04, Vol.660, p.A103
Main Authors: Williamson, H. N., Nilsson, H., Stenberg Wieser, G., Moeslinger, A., Goetz, C.
Format: Article
Language:English
Subjects:
Comets: individual: comet 67P/Churyumov-Gerasimenko
Methods: data analysis
Plasmas
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Summary:Context. The ionosphere of a comet is known to deflect the solar wind through mass loading, but the interaction is dependent on cometary activity. We investigate the details of this process at comet 67P using the Rosetta Ion Composition Analyzer. Aims. This study aims to compare the interaction of the solar wind and cometary ions during two different time periods in the Rosetta mission. Methods. We compared both the integrated ion moments (density, velocity, and momentum flux) and the velocity distribution functions for two days, four months apart. The velocity distribution functions were projected into a coordinate system dependent on the magnetic field direction and averaged over three hours. Results. The first case shows highly scattered H + in both ion moments and velocity distribution function. The He 2+ ions are somewhat scattered, but less so, and appear more like those of H 2 O + pickup ions. The second case shows characteristic evidence of mass-loading, where the solar wind species are deflected, but the velocity distribution function is not significantly changed. Conclusions. The distributions of H + in the first case, when compared to He 2+ and H 2 O + pickup ions, are indicative of a narrow cometosheath on the scale of the H + gyroradius. Thus, He 2+ and H 2 O + , with larger gyroradii, are largely able to pass through this cometosheath. An examination of the momentum flux tensor suggests that all species in the first case have a significant non-gyrotropic momentum flux component that is higher than that of the second mass-loaded case. Mass loading is not a sufficient explanation for the distribution functions and momentum flux tensor in the first case, and so we assume this is evidence of bow shock formation.
ISSN:0004-6361
1432-0746
1432-0746
DOI:10.1051/0004-6361/202142461