Cryovolcanic rates on Ceres revealed by topography

M. M. Sori; H. G. Sizemore; S. Byrne; A. M. Bramson; Michael T. Bland; N. T. Stein; C. T. Russell

doi:10.1038/s41550-018-0574-1

Cryovolcanic rates on Ceres revealed by topography

Nature Astronomy

By: M. M. Sori, H. G. Sizemore, S. Byrne, A. M. Bramson, Michael T. Bland, N. T. Stein, and C. T. Russell

https://doi.org/10.1038/s41550-018-0574-1

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Abstract

Cryovolcanism, defined here as the extrusion of icy material from depth, may be an important planetary phenomenon in shaping the surfaces of many worlds in the outer Solar System and revealing their thermal histories^1,2,3. However, the physics, chemistry and ubiquity of this geologic process remain poorly understood, especially in comparison to the better-studied silicate volcanism on the terrestrial planets. Ceres is the only plausibly cryovolcanic world to be orbited by a spacecraft up to now, making it the best opportunity to test the importance of cryovolcanism on bodies in the outer Solar System and compare its effects to silicate volcanism on terrestrial planets. Here, we analyse images from NASA’s Dawn mission⁴ and use the finite element method to show that Ceres has experienced cryovolcanism throughout its geologic history, with an average cryomagma extrusion rate of ~10⁴ m³ yr⁻¹. This result shows that volcanic phenomena are important on Ceres, but orders of magnitude less so than on the terrestrial planets.

Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Cryovolcanic rates on Ceres revealed by topography
Series title	Nature Astronomy
DOI	10.1038/s41550-018-0574-1
Volume	2
Year Published	2018
Language	English
Publisher	SpringerNature
Contributing office(s)	Astrogeology Science Center
Description	5 p.
First page	946
Last page	950
Other Geospatial	Ceres
Google Analytic Metrics	Metrics page