Turbulent ocean could explain Europa’s chaotic ice

A simulation (left) of Europa’s global ocean dynamics shows warmer (red) and cooler (blue) temperatures where more heat is delivered to the ice shell near the equator. That uneven heating could explain the nonuniform pattern of ice on the moon's surface (right).

Model image: J. Wicht; Europa: Univ. of Arizona, JPL/NASA

Europa, the sixth-closest moon of Jupiter, is covered with icy chunks that have been cracked and crunched into chaotic patterns.

Scientists aren’t exactly sure what processes form and shape the patterns. But new computer simulations show turbulent global ocean currents that move Europa’s internal heat to the surface most effectively in regions closest to the moon’s equator.

That varied heat distribution pattern could allow more changes to the ice features and could explain the formation of the chaotic ice patterns at the moon’s lower latitudes, researchers report December 1 in Nature Geoscience.

It’s not yet clear whether the model, scaled up from laboratory experiments and simulations, fully captures the moon’s dynamics. But, without a space mission to Europa, the model provide scientists with the best understanding to date of the moon’s ice and ocean, according to a News & Views article accompanying the research.

Ashley Yeager is the associate news editor at Science News. She has worked at The Scientist, the Simons Foundation, Duke University and the W.M. Keck Observatory, and was the web producer for Science News from 2013 to 2015. She has a bachelor’s degree in journalism from the University of Tennessee, Knoxville, and a master’s degree in science writing from MIT.

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