Heat transfer of ascending cryomagma on Europa

Jupiter's moon Europa has a relatively young surface (60–90Myr on average), which may be due in part to cryovolcanic processes. Current models for both effusive and explosive cryovolcanism on Europa may be expanded and enhanced by linking the potential for cryovolcanism at the surface to subsur...

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Bibliographic Details
Published in:Journal of volcanology and geothermal research 2016-06, Vol.319, p.66-77
Main Authors: Quick, Lynnae C., Marsh, Bruce D.
Format: Article
Language:English
Subjects:
Ascent
Conduits
Cryovolcanism
Diapirs
Europa
Heat transfer
Jupiter (planet)
Jupiter satellites
Magmatism
Mathematical models
Subsurface processes
Transport
Volcanism
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Summary:Jupiter's moon Europa has a relatively young surface (60–90Myr on average), which may be due in part to cryovolcanic processes. Current models for both effusive and explosive cryovolcanism on Europa may be expanded and enhanced by linking the potential for cryovolcanism at the surface to subsurface cryomagmatism. The success of cryomagma transport through Europa's crust depends critically on the rate of ascent relative to the rate of solidification. The final transport distance of cryomagma is thus governed by initial melt volume, ascent rate, overall ascent distance, transport mechanism (i.e., diapirism, diking, or ascent in cylindrical conduits), and melt temperature and composition. The last two factors are especially critical in determining the budget of expendable energy before complete solidification. Here we use these factors as constraints to explore conditions under which cryomagma may arrive at Europa's surface to facilitate cryovolcanism. We find that 1–5km radius warm ice diapirs ascending from the base of a 10km thick stagnant lid can reach the shallow subsurface in a partially molten state. Cryomagma transport may be further facilitated if diapirs travel along pre-heated ascent paths. Under certain conditions, cryolava transported from 10km depths in tabular dikes or pipe-like conduits may reach the surface at temperatures exceeding 250K. Ascent rates for these geometries may be high enough that isothermal transport is approached. Cryomagmas containing significant amounts of low eutectic impurities can also be delivered to Europa's surface by propagating dikes or pipe-like conduits. •This study aims to link cryovolcanism at Europa's surface to the subsurface transport of cryomagmatic fluids•We investigate heat transfer associated with cryomagma ascent on Europa•Models for heat transfer in diapirs, dikes, and pipe-like conduits are presented•In some cases, fluids transported in tabular dikes or pipe-like conduits may reach the surface at temperatures exceeding 250K•Warm ice may be brought to Europa's surface by diapirs that traverse preheated ascent paths
ISSN:0377-0273
1872-6097
DOI:10.1016/j.jvolgeores.2016.03.018