Journal article
Flows, Fields, and Forces in the Mars‐Solar Wind Interaction
Journal of geophysical research. Space physics, Vol.122(11), pp.11,320-11,341
11/2017
DOI: 10.1002/2017JA024772
Abstract
We utilize suprathermal ion and magnetic field measurements from the Mars Atmosphere and Volatile EvolutioN (MAVEN) mission, organized by the upstream magnetic field, to investigate the morphology and variability of flows, fields, and forces in the Mars‐solar wind interaction. We employ a combination of case studies and statistical investigations to characterize the interaction in both quasi‐parallel and quasi‐perpendicular regions and under high and low solar wind Mach number conditions. For the first time, we include a detailed investigation of suprathermal ion temperature and anisotropy. We find that the observed magnetic fields and suprathermal ion moments in the magnetosheath, bow shock, and upstream regions have observable asymmetries controlled by the interplanetary magnetic field, with particularly large asymmetries found in the ion parallel temperature and anisotropy. The greatest temperature anisotropies occur in quasi‐perpendicular regions of the magnetosheath and under low Mach number conditions. These results have implications for the growth and evolution of wave‐particle instabilities and their role in energy transport and dissipation. We utilize the measured parameters to estimate the average ion pressure gradient, J × B, and v × B macroscopic force terms. The pressure gradient force maintains nearly cylindrical symmetry, while the J × B force has larger asymmetries and varies in magnitude in comparison to the pressure gradient force. The v × B force felt by newly produced planetary ions exceeds the other forces in magnitude in the magnetosheath and upstream regions for all solar wind conditions.
Key Points
MAVEN measures the global distribution of suprathermal ions and magnetic fields around Mars, from which we can derive macroscopic forces
The flows, fields, and forces in the Mars‐solar wind interaction vary with both upstream magnetic field orientation and Mach number
Ion temperature and temperature anisotropy vary spatially and with solar wind parameters, with implications for plasma instabilities
Plain Language Summary
The solar wind that flows out from the Sun and pervades our solar system is largely deflected around Mars by its interaction with the upper atmosphere. However, this interaction also transfers energy to planetary ions, giving some of them sufficient velocity to escape from Mars. Therefore, the Mars‐solar wind interaction has implications for the long‐term evolution of the Martian atmosphere and its habitability. In this work, we study the structure and variability of the interaction and the macroscopic forces responsible for decelerating and deflecting the solar wind around Mars as well as those that accelerate planetary ions. We also investigate the asymmetries in this interaction and how they change in response to variations in the incoming solar wind flow and the magnetic field carried with the flow.
Details
- Title: Subtitle
- Flows, Fields, and Forces in the Mars‐Solar Wind Interaction
- Creators
- J. S Halekas - University of IowaD. A Brain - University of Colorado BoulderJ. G Luhmann - University of California, BerkeleyG. A DiBraccio - Goddard Space Flight CenterS Ruhunusiri - University of IowaY Harada - University of IowaC. M Fowler - University of Colorado BoulderD. L Mitchell - University of California, BerkeleyJ. E. P Connerney - Goddard Space Flight CenterJ. R Espley - Goddard Space Flight CenterC Mazelle - Université de ToulouseB. M Jakosky - University of Colorado Boulder
- Resource Type
- Journal article
- Publication Details
- Journal of geophysical research. Space physics, Vol.122(11), pp.11,320-11,341
- DOI
- 10.1002/2017JA024772
- ISSN
- 2169-9380
- eISSN
- 2169-9402
- Number of pages
- 22
- Grant note
- National Aeronautics and Space Administration (NASA)
- Language
- English
- Date published
- 11/2017
- Academic Unit
- Physics and Astronomy
- Record Identifier
- 9984200042802771
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