The Global Shape, Gravity Field, and Libration of Enceladus
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1.
California Institute of Technology
Abstract
In order to improve our understanding of the interior structure of Saturn's small moon Enceladus, we reanalyze radiometric tracking and onboard imaging data acquired by the Cassini spacecraft during close encounters with the moon. We compute the global shape, gravity field, and rotational parameters of Enceladus in a reference frame consistent with the International Astronomical Union's definition, where the center of the Salih crater is located at −5° East longitude. We recover a quadrupole gravity field with J3 and a forced libration amplitude of 0.091° ± 0.009° (3-σ). We also compute a global shape model using a stereo-photoclinometry technique with a global resolution of 500 m, although some local maps have higher resolutions ranging from 25 to 100 m. While our overall results are generally consistent with previous studies, we infer a thicker 27–33 km mean ice shell, a thinner 21–26 km mean ocean thickness, and a mean core density range of 2,270–2,330 kg/m3.
Copyright and License
© 2024 Jet Propulsion Laboratory, California Institute of Technology and The Authors. Government sponsorship acknowledged. This is an open access article under the terms of the Creative Commons Attribution-NonCommercial License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited and is not used for commercial purposes
Acknowledgement
The authors acknowledge the extensive efforts of the MSL Curiosity rover engineering and science operations teams as well as the MSL Sedimentology and Stratigraphy Working Group. Part of this research was carried out at the Jet Propulsion Laboratory, California Institute of Technology, under a contract with the National Aeronautics and Space Administration. Mastcam mosaics were processed by the Mastcam team at Malin Space Science Systems. We thank Libby Ives and Michael Thorpe for the comprehensive reviews that greatly improved the quality of this manuscript. S. Gwizd and C. Fedo acknowledge funding from NASA/JPL subcontract #1546201.
Contributions
Conceptualization: R. S. Park, J. T. Keane, A. S. Konopliv, J. E. Riedel
Formal analysis: R. S. Park, N. Mastrodemos, R. A. Jacobson, A. Berne, A. T. Vaughan, D. J. Hemingway, E. J. Leonard, J. T. Keane, S. Vance
Funding acquisition: R. S. ParkInvestigation: R. S. Park, J. C. Castillo-Rogez
Methodology: R. S. Park, N. Mastrodemos, R. A. Jacobson, A. Berne, D. J. Hemingway, E. J. Leonard, J. C. Castillo-Rogez, J. T. Keane, F. Nimmo, S. Vance
Data Availability
The code repository for the MMGIS interface can be accessed through (https://github.com/NASA-AMMOS/MMGIS) and is detailed by Calef et al. (2019). The HiRISE mosaic used through the MMGIS interface can be accessed through Calef and Parker (2016). Data derived from HiRISE (McEwen, 2005) and CTX (Malin, 2007) images can also be accessed through the NASA Planetary Data System Geosciences Node (https://pds-geosciences.wustl.edu/missions/mro/default.htm). All Mastcam (Malin, 2013) and MAHLI (Edgett, 2013a, 2013b) images used in this manuscript may be accessed through the NASA Planetary Data System Cartography and Imaging Sciences Node (https://pds-imaging.jpl.nasa.gov/volumes/msl.html).
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Additional details
- ISSN
- 2169-9100
- DOI
- 10.1029/2023JE008054
- Jet Propulsion Laboratory
- 1546201
- Caltech groups
- Division of Geological and Planetary Sciences