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Ceres' partial differentiation: undifferentiated crust mixing with a water-rich mantle

Neumann, Wladimir and Jaumann, R and Castillo-Rogez, Julie and Raymond, Carol A. and Russell, Christopher T. (2020) Ceres' partial differentiation: undifferentiated crust mixing with a water-rich mantle. Astronomy & Astrophysics, 633, A117. EDP Sciences. doi: 10.1051/0004-6361/201936607. ISSN 0004-6361.

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Official URL: https://www.aanda.org/articles/aa/abs/2020/01/aa36607-19/aa36607-19.html

Abstract

Aims. We model thermal evolution and water-rock differentiation of small ice-rock objects that accreted at different heliocentric distances, while also considering migration into the asteroid belt for Ceres. We investigate how water-rock separation and various cooling processes influence Ceres’ structure and its thermal conditions at present. We also draw conclusions about the presence of liquids and the possibility of cryovolcanism. Methods. We calculated energy balance in bodies heated by radioactive decay and compaction-driven water-rock separation in a three-component dust-water/ice-empty pores mixture, while also taking into consideration second-order processes, such as accretional heating, hydrothermal circulation, and ocean or ice convection. Calculations were performed for varying accretion duration, final size, surface temperature, and dust/ice ratio to survey the range of possible internal states for precursors of Ceres. Subsequently, the evolution of Ceres was considered in five sets of simulated models, covering different accretion and evolution orbits and dust/ice ratios. Results. We find that Ceres’ precursors in the inner solar system could have been both wet and dry, while in the Kuiper belt, they retain the bulk of their water content. For plausible accretion scenarios, a thick primordial crust may be retained over several Gyr, following a slow differentiation within a few hundreds of Myr, assuming an absence of destabilizing impacts. The resulting thermal conditions at present allow for various salt solutions at depths of ≲10 km. The warmest present subsurface is obtained for an accretion in the Kuiper belt and migration to the present orbit. Conclusions. Our results indicate that Ceres’ material could have been aqueously altered on small precursors. The modeled structure of Ceres suggests that a liquid layer could still be present between the crust and the core, which is consistent with Dawn observations and, thus, suggests accretion in the Kuiper belt. While the crust stability calculations indicate crust retention, the convection analysis and interior evolution imply that the crust could still be evolving.

Item URL in elib:https://elib.dlr.de/139024/
Document Type:Article
Title:Ceres' partial differentiation: undifferentiated crust mixing with a water-rich mantle
Authors:
AuthorsInstitution or Email of AuthorsAuthor's ORCID iDORCID Put Code
Neumann, WladimirUNSPECIFIEDhttps://orcid.org/0000-0003-1932-602XUNSPECIFIED
Jaumann, RUNSPECIFIEDUNSPECIFIEDUNSPECIFIED
Castillo-Rogez, JulieJet Propulsion Laboratory, California Institute of Technology,UNSPECIFIEDUNSPECIFIED
Raymond, Carol A.Jet Propulsion Laboratory, California Institute of Technology, Pasadena, CA, United States.UNSPECIFIEDUNSPECIFIED
Russell, Christopher T.Institute of Geophysics, UCLA, Los Angeles, CA, United States.UNSPECIFIEDUNSPECIFIED
Date:January 2020
Journal or Publication Title:Astronomy & Astrophysics
Refereed publication:Yes
Open Access:Yes
Gold Open Access:No
In SCOPUS:Yes
In ISI Web of Science:Yes
Volume:633
DOI:10.1051/0004-6361/201936607
Page Range:A117
Publisher:EDP Sciences
ISSN:0004-6361
Status:Published
Keywords:minor planets asteroids Ceres planets and satellites convection
HGF - Research field:Aeronautics, Space and Transport
HGF - Program:Space
HGF - Program Themes:Space Exploration
DLR - Research area:Raumfahrt
DLR - Program:R EW - Space Exploration
DLR - Research theme (Project):R - Exploration of the Solar System
Location: Berlin-Adlershof
Institutes and Institutions:Institute of Planetary Research > Asteroids and Comets
Institute of Planetary Research > Planetary Geology
Deposited By: Neumann, Wladimir
Deposited On:04 Dec 2020 08:32
Last Modified:24 Oct 2023 11:09

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