Compositional diapirism as the origin of the low‐albedo terrain and vaporization at midlatitude on Ceres

Dake, S.; Kurita, Kei

doi:10.1002/2014je004695

Cited by 11 publications

(11 citation statements)

References 48 publications

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“…The critical viscosity for the development of Rayleigh-Taylor instabilities at the base of the crust is calculated as in Shoji & Kurita (2014) (see also Rubin et al 2014;Formisano et al 2016). We can confirm crustal viscosities calculated by Shoji & Kurita (2014), since they match approximately those that we calculated using the harmonic mean. Since these authors assume a higher H 2 O fraction, the rheology of the crust will be dominated by ice, and the calculation of the mixture viscosity according to the Reuss model is appropriate in their case.…”

Section: Crust Stabilitysupporting

confidence: 74%

“…The stability of Ceres' crust was studied by Shoji & Kurita (2014) and by Formisano et al (2016) for mixed ice-rock compositions by comparing the mixture viscosity with a critical viscosity for the development of Rayleigh-Taylor instabilities. Considering a composition that is dominated by phyllosilicates (see above) and calculating viscosities of each species involved, bulk viscosity can be calculated as their mean value (see, e.g., De Meer et al 2002;Grocott et al 2009;Dygert et al 2016).…”

Section: Crust Stabilitymentioning

confidence: 99%

“…Ceres' crust stability was studied by Shoji & Kurita (2014) and by Formisano et al (2016) for mixed ice-rock compositions by comparing the mixture viscosity with a critical viscosity for the development of Rayleigh-Taylor instabilities. Shoji & Kurita (2014) assumed a higher H 2 O fraction than in our study and a crust rheology dominated by ice.…”

Section: Comparison With Previous Modelsmentioning

confidence: 99%

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

Neumann

Jaumann

Castillo‐Rogez

et al. 2020

A&A

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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.

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Section: Crust Stabilitysupporting

confidence: 74%

Section: Crust Stabilitymentioning

confidence: 99%

Section: Comparison With Previous Modelsmentioning

confidence: 99%

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

Neumann

Jaumann

Castillo‐Rogez

et al. 2020

A&A

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“…Overturn was accomplished by compositional diapirism from a small subsurface ocean if Ceres formed 4–7 Myr after CAIs; if Ceres formed with more 26 Al, <4 Myr after CAIs, then overturn was accomplished by foundering of a thin (∼4 km) crust over a deep ocean. In contrast, Travis et al [] predict overturn by convection throughout Ceres's history, and Shoji and Kurita [] predict overturn by diapirism over Ceres's history but only near its equator. Crater counts to derive Ceres's surface age can test these predictions.…”

Section: Discussionmentioning

confidence: 99%

“…Here η ∼ 10 14 (1 − ϕ / ϕ m ) −2 ∼10 16 Pas is the viscosity of primordial, solids‐laden ice at the liquid‐ice interface, and Z 0 ∼1 km is the size of the perturbation initiating the RT instability. From equation , the timescale for a diapir of diameter 40 km and density ≈ 1500 kg m −3 to buoyantly rise 10 km by Stokes flow, assuming an ice viscosity

η = 1 0^{16} \exp [20 (273 K / T - 1)]

Pas [ Shoji and Kurita , ], is about 250 years for ice at 273 K near the liquid‐ice interface, increasing to 50 Myr in ice at 170 K. While diapirs ascend to the surface, fingers of ice bearing fines and chondrules sink into the liquid layer where they melt, delivering more chondrules to the core and fines to the ocean (Figure ). RT instabilities keep generating diapirs containing liquid and fines until the entire crust has overturned, yielding a mantle of refrozen ice mixed with aqueously altered fines, all within the first ≈60 Myr of Ceres's evolution.…”

Section: Differentiation and Origin Of A Muddy Ice Mantlementioning

confidence: 99%

Geochemistry, thermal evolution, and cryovolcanism on Ceres with a muddy ice mantle

Neveu

Desch

2015

Geophysical Research Letters

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We present a model of the internal evolution of Ceres consistent with pre‐Dawn observations and preliminary data returned by Dawn. We assume that Ceres accreted ice and both micron‐ and millimeter‐sized rock particles and that micron‐sized fines stayed suspended in liquid during differentiation. We conclude that aqueously altered grains were emplaced on Ceres's surface during the first tens of megayears of its evolution. Our geochemical simulations suggest that Ceres's unusual surface mineralogy is consistent with aqueous alteration of CM material, possibly by NH3‐bearing fluid. Thermal evolution simulations including insulating fines yield present‐day liquid at depth if Ceres has a small core or no core at all; otherwise, they yield temperatures at the core‐mantle boundary of 240–250 K, just warm enough for chloride brines to persist and be freezing today. We hypothesize that ongoing freezing may overpressurize liquid or briny reservoirs, driving cryovolcanic outflow whose surface expression may have been observed by Dawn at Ceres's “bright spots.” These outflows may contribute to the water vapor being produced at Ceres.

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A review of aerosol optical properties and radiative effects

et al. 2014

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Compositional diapirism as the origin of the low‐albedo terrain and vaporization at midlatitude on Ceres

Cited by 11 publications

References 48 publications

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

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

Geochemistry, thermal evolution, and cryovolcanism on Ceres with a muddy ice mantle

A review of aerosol optical properties and radiative effects

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