Data in support of manuscript titled: "Partitioning of crystalline and amorphous phases during freezing of simulated Enceladus ocean fluids"

Published: 20 November 2020| Version 1 | DOI: 10.17632/spmww2myjs.1
Mark Fox-Powell,


Saturn’s ice-covered moon Enceladus may contain the requisite conditions for life. Its potentially habitable subsurface ocean is vented into space as large ice-rich cryovolcanic plumes that can be sampled by spacecraft, acting as a window to the ocean below. However, little is known about how Enceladus’ ocean fluids evolve as they freeze. Using cryo-imaging techniques, we investigated solid phases produced by freezing simulated Enceladean ocean fluids at endmember cooling rates. Our results show that under flash-freezing conditions (>10 K s-1), Enceladus-relevant fluids undergo segregation, whereby the precipitation of ice templates the formation of brine vein networks. The high solute concentrations and confined nature of these brine veins means that salt crystallizaiton is kinetically inhibited and glass formation (vitrification) can occur at lower cooling rates than typically required for vitrification of a bulk solution. Crystalline salts also form if flash-frozen fluids are re-warmed. The 10 µm-scale distribution of salt phases produced by this mechanism differs markedly from that of gradually cooled (~1 K min-1) fluids, showing that they inherit signatures of their constrasting formation conditions. The mineralogy of cryogenic carbonates can be used as a probe for cooling rate and parent fluid pH. Our findings reveal possible endmember routes for solid phase production from Enceladus’ ocean fluids and mechanisms for generating compositional heterogeneity within ice particles on a sub-10 µm scale. This has implications for understanding how Enceladus’ ocean constituents are incorporated into icy particles and delivered to space.


Steps to reproduce

See README.txt


University of St Andrews School of Earth and Environmental Sciences


Planetary Geochemistry