Slurry extrusion on Ceres from a convective mud-bearing mantle

Ceres is a 940-km-diameter dwarf planet that is predominantly composed of silicates and water ice. In Ceres’ partially differentiated interior, extrusive processes have led to the emplacement on its surface of domes with heights of kilometres. Here we report the analysis of a gravity anomaly detecte...

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Veröffentlicht in:	Nature geoscience 2019-07, Vol.12 (7), p.505-509
Hauptverfasser:	Ruesch, Ottaviano, Genova, Antonio, Neumann, Wladimir, Quick, Lynnae C., Castillo-Rogez, Julie C., Raymond, Carol A., Russell, Christopher T., Zuber, Maria T.
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Sprache:	eng
Schlagworte:	704/445/125 704/445/210 704/445/848 Bearing Brines Ceres asteroid Computational fluid dynamics Convection Domes Dwarf planets Earth and Environmental Science Earth Sciences Earth System Sciences Extrusion Fluids Geochemistry Geology Geophysics/Geodesy Gravity Gravity anomalies Icy satellites Mantle Mantle plumes Mineralogy Morphology Mud Planetary surfaces Rheological properties Rheology Saline water Silicates Slurries Spacecraft Uplift Water ice
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creator	Ruesch, Ottaviano Genova, Antonio Neumann, Wladimir Quick, Lynnae C. Castillo-Rogez, Julie C. Raymond, Carol A. Russell, Christopher T. Zuber, Maria T.
description	Ceres is a 940-km-diameter dwarf planet that is predominantly composed of silicates and water ice. In Ceres’ partially differentiated interior, extrusive processes have led to the emplacement on its surface of domes with heights of kilometres. Here we report the analysis of a gravity anomaly detected by the Dawn spacecraft, which is associated with the geologically recent dome Ahuna Mons. By modelling the anomaly with a mass concentration method, we determine that the subsurface structure includes a regional mantle uplift, which we interpret as a plume. This structure is the probable source of fluids forming Ahuna Mons and, together with constraints from the dome’s morphology, indicates a rheological regime corresponding to a slurry of brine and solid particles. We propose that the properties of such a solid–liquid mixture can explain the viscous relaxation and the mineralogy of the dome. The presence of a plume and of slurry material indicate recent convection in a mud-bearing mantle. The inferred slurry extrusion on Ceres differs from the water-dominated cryovolcanism of icy satellites, and so reveals compositional and rheological diversity in extrusive phenomena on planetary surfaces. Ahuna Mons dome on Ceres formed by extrusion of a mixture of brine and solids sourced from a muddy mantle plume, according to numerical modelling of slurry rheology and a gravity anomaly found by the Dawn mission.
doi_str_mv	10.1038/s41561-019-0378-7
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subjects	704/445/125 704/445/210 704/445/848 Bearing Brines Ceres asteroid Computational fluid dynamics Convection Domes Dwarf planets Earth and Environmental Science Earth Sciences Earth System Sciences Extrusion Fluids Geochemistry Geology Geophysics/Geodesy Gravity Gravity anomalies Icy satellites Mantle Mantle plumes Mineralogy Morphology Mud Planetary surfaces Rheological properties Rheology Saline water Silicates Slurries Spacecraft Uplift Water ice
title	Slurry extrusion on Ceres from a convective mud-bearing mantle
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