NASA Scientists Determine Europa Likely Spun on a Tilted Axis

NASA Scientists Find Evidence that Europa Likely Spun on a Tilted Axis at Some Point

The distinctive cracks crisscrossing Europa’s icy surface are clues to the stresses that this moon of Jupiter has experienced. This mosaic image was taken by NASA’s Galileo satellite, which flew past this moon of Jupiter six times between 1996 and 1999. Credit: NASA/JPL-Caltech/University of Arizona

By using data from NASA’s Galileo spacecraft to analyze the distinctive cracks lining the surface of Europa, NASA scientists determined that Europa likely rotated around a tilted axis at some point.

This tilt could influence calculations of how much of Europa’s history is recorded in its frozen shell, how much heat is generated by tides in its ocean, and even how long the ocean has been liquid.

“One of the mysteries of Europa is why the orientations of the long, straight cracks called lineaments have changed over time. It turns out that a small tilt, or obliquity, in the spin axis, sometime in the past, can explain a lot of what we see,” said Alyssa Rhoden, a postdoctoral fellow with Oak Ridge Associated Universities who is working at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. She is the lead author of a paper in the September–October issue of Icarus that describes the results.

Europa’s network of crisscrossing cracks serves as a record of the stresses caused by massive tides in the moon’s global ocean. These tides occur because Europa travels around Jupiter in a slightly oval-shaped orbit. When Europa comes closer to the planet, the moon gets stretched like a rubber band, with the ocean height at the long ends rising nearly 100 feet (30 meters). That’s roughly as high as the 2004 tsunami in the Indian Ocean, but it happens on a body that measures only about one-quarter of Earth’s diameter. When Europa moves farther from Jupiter, it relaxes back into the shape of a ball.

The moon’s ice layer has to stretch and flex to accommodate these changes, but when the stresses become too great, it cracks. The puzzling part is why the cracks point in different directions over time, even though the same side of Europa always faces Jupiter.

A leading explanation has been that Europa’s frozen outer shell might rotate slightly faster than the moon orbits Jupiter. If this out-of-sync rotation does occur, the same part of the ice shell would not always face Jupiter.

Rhoden and her Goddard co-author Terry Hurford put that idea to the test using images taken by NASA’s Galileo spacecraft during its nearly eight-year mission, which began in 1995. “Galileo produced many paradigm shifts in our understanding of Europa, one of which was the phenomena of out-of-sync rotation,” said Claudia Alexander of NASA’s Jet Propulsion Laboratory in Pasadena, California, who was the project manager when the Galileo mission ended.

Rhoden and Hurford compared the pattern of cracks in a key area near Europa’s equator to predictions based on three different explanations. The first set of predictions was based on the rotation of the ice shell. The second set assumed that Europa was spinning around a tilted axis, which, in turn, made the orientation of the pole change over time. This effect, called precession, looks very much like what happens when a spinning toy top has started to slow down and wobble. The third explanation was that the cracks were laid out in random directions.

The researchers got the best performance when they assumed that precession had occurred, caused by a tilt of about one degree, and combined this effect with some random cracks, said Rhoden. Out-of-sync rotation was surprisingly unsuccessful, in part because Rhoden found an oversight in the original calculations for this model.

Long Stressed Europa Likely Off Kilter at One Time

This close-up of the Bright Plains region near the equator of Europa reveals layer upon layer of cracks (left). By interpreting the directions of the long, straight cracks called lineaments (right), NASA scientists determined that Europa probably rotated around a tilted axis at some point. Credit: NASA/JPL-Caltech/University of Arizona/Goddard

The results are compelling enough to satisfy Richard Greenberg, the University of Arizona professor who had earlier proposed the idea of out-of-sync rotation.

“By extracting new information from the Galileo data, this work refines and improves our understanding of the very unusual geology of Europa,” said Greenberg, who was Rhoden’s undergraduate advisor and Hurford’s graduate advisor.

The existence of tilt would not rule out the out-of-sync rotation, according to both Rhoden and Greenberg. But it does suggest that Europa’s cracks may be much more recent than previously thought. That’s because the spin pole direction may change by as much as a few degrees per day, completing one precession period over several months. On the other hand, with the leading explanation, one full rotation of the ice sheet would take roughly 250,000 years. In either case, several rotations would be needed to explain the crack patterns.

A tilt also could affect the estimates of the age of Europa’s ocean. Because tidal forces are thought to generate the heat that keeps Europa’s ocean liquid, a tilt in the spin axis might suggest that more heat is generated by tidal forces. This, in turn, might keep the ocean liquid longer.

The analysis does not specify when the tilt would have occurred. So far, measurements have not been made of the tilt of Europa’s axis, and this is one goal scientists have for Europa missions in the future.

“One of the fascinating open questions is how active Europa still is. If researchers pin down Europa’s current spin axis, then our findings would allow us to assess whether the clues we are finding on the moon’s surface are consistent with the present-day conditions,” said Rhoden.

Reference: “Lineament azimuths on Europa: Implications for obliquity and non-synchronous rotation” by Alyssa Rose Rhoden and Terry A. Hurford, 11 July 2013, Icarus.
DOI: 10.1016/j.icarus.2013.06.029

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