Evolution of Occator Crater on (1) Ceres

The dwarf planet Ceres (diameter 939 km) is the largest object in the main asteroid belt. Recent investigations suggest that Ceres is a thermally evolved, volatile-rich body with potential geological activity, a body which was never completely molten but possibly differentiated into a rocky core, an...

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Published inThe Astronomical journal Vol. 153; no. 3; p. 112
Main Authors Nathues, A., Platz, T., Thangjam, G., Hoffmann, M., Mengel, K., Cloutis, E. A., Corre, L. Le, Reddy, V., Kallisch, J., Crown, D. A.
Format Journal Article
LanguageEnglish
Published United States The American Astronomical Society 01.03.2017
Subjects
ABSORPTION
ABSORPTION SPECTROSCOPY
ASTEROIDS
ASTROPHYSICS, COSMOLOGY AND ASTRONOMY
Bright spots
BRINES
CAMERAS
CARBONATES
Ceres asteroid
CRATERS
Domes
EVOLUTION
Fracture mechanics
FRACTURES
GASES
ICE
Imaging
INFRARED SPECTRA
INFRARED SPECTROMETERS
minor planets, asteroids: general
PLANETS
SURFACES
VISIBLE SPECTRA
WATER
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Summary:The dwarf planet Ceres (diameter 939 km) is the largest object in the main asteroid belt. Recent investigations suggest that Ceres is a thermally evolved, volatile-rich body with potential geological activity, a body which was never completely molten but possibly differentiated into a rocky core, an ice-rich mantle, and which may contain remnant internal liquid water. Thermal alteration and exogenic material infall contribute to producing a (dark) carbonaceous chondritic-like surface containing ammoniated phyllosilicates. Here we report imaging and spectroscopic analyses of Occator crater derived from the Framing Camera and the Visible and Infrared Spectrometer onboard Dawn. We found that the central bright spot (Cerealia Facula) of Occator is ∼30 Myr younger than the crater itself. The central spot is located in a central pit which contains a dome that is spectrally homogenous, exhibiting absorption features that are consistent with carbonates. Multiple radial fractures across the dome indicate an extrusive formation process. Our results lead us to conclude that the floor region was subject to past endogenic activity. Dome and bright material in its vicinity formed likely due to a long-lasting, periodic, or episodic ascent of bright material from a subsurface reservoir rich in carbonates. Originally triggered by an impact event, gases, possibly dissolved from a subsurface water/brine layer, enabled material rich in carbonates to ascend through fractures and be deposited onto the surface.
Bibliography:AAS02761
The Solar System, Exoplanets, and Astrobiology
ObjectType-Article-1
SourceType-Scholarly Journals-1
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ISSN:0004-6256
1538-3881
1538-3881
DOI:10.3847/1538-3881/153/3/112