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Space Topics: Jupiter

Callisto

Click to enlarge > Callisto in color Galileo captured this global view of Callisto on its 30th orbit of Jupiter, on May 26, 2001. The filters used for this image cover a broader range of the spectrum than human eyes can see. Galileo ranged from 740,000 to 744,000 kilometers from Callisto when it took this image, at a phase angle of just 3°. Image scale is 7.5 kilometers per pixel. Credit: NASA / JPL / Ted Stryk

Diameter: 4,820.6 kilometers -- 0.3779 Earth diameters -- 12th largest solar system body
Orbital distance: 1,882,700 kilometers from Jupiter
Orbital period: 16.689 days
Discovery: 1610 by Galileo Galilei

Compared to the dynamic and varied surfaces of Io, Europa, and Ganymede, Callisto’s looks boring by comparison.  It is one of the most heavily cratered bodies in the solar system, indicating that its surface is very, very old, roughly 4 billion years in age.  Over geologic time, the originally sharp-edged craters “relaxed,” so Callisto’s craters look more subdued than those on Earth’s Moon.

Callisto is believed to have a very primitive interior, in which its component ice and rock are mostly jumbled together, rather than being separated into layers as they are in nearly every other large body in the solar system.  Callisto likely never got warm enough for the contrast in density between ice and rock to drive the differentiation of its interior.  It has been a very cold, very inactive world for a long time.  Strangely, though, Galileo did detect a thin liquid layer at a depth of about 200 kilometers (120 miles) below Callisto’s surface.

Galileo’s close-up views revealed that there was some previously unexplained weathering process eroding jagged, icy peaks and leaving crater floors filled with a strange, dark dust.  Scientists proposed that the ice in the bright peaks may sublime, leaving behind silicate dust, which then drifts downward to fill crater floors.  The dark dust would be relatively warmer than the bright icy peaks; sublimation near dust deposits would be enhanced, accelerating the process of peak erosion.

	Click to enlarge > Callisto in color Galileo captured this global view of Callisto on its 11th orbit of Jupiter, on November 5, 1997. The filters used for this image cover a broader range of the spectrum than human eyes can see. Galileo was 687,000 kilometers from Callisto when it took this image, at a phase angle of just 1°. Image scale is 6.9 kilometers per pixel. The image was reconstructed from the original data by Ted Stryk. About 10% of the right side of the disk was marred by data dropouts; Stryk reconstructed missing data from images taken through other filters. Credit: NASA / JPL / Ted Stryk
	Click to enlarge > Callisto from New Horizons New Horizons captured this image of Callisto as it zipped by the Jupiter system on February 27, 2007. With a diameter of about 4,800 kilometers, Callisto is the second largest moon of Jupiter and the 12th largest object in the solar system. Credit: NASA / JHUAPL / SwRI
	Click to enlarge > Crater degredation on Callisto and Ganymede Credit: NASA / JPL / Jeff Moore
	Click to enlarge > Debris slides on Callisto Callisto is unique among the Galilean satellites of Jupiter for having debris avalanches from oversteepened crater walls. Credit: NASA / JPL / Jeff Moore
	Click to enlarge > A model for the degradation of Callisto's topography In this model, Callisto starts out with a surface roughened by impacts. Volatile materials -- water ice and, probably, carbon dioxide ice -- sublime from this surface and then get redeposited. Physical models suggest that the floors of these craters will experience net sublimation, while the peaks will experience net deposition of frost, a process that accelerates as the floor accumulates a lag deposit of dark materials (which absorb more solar radiation and thus get warmer) and the peaks accumulate a deposit of bright, reflective frost. Bedrock is only exposed in the steepest part of the crater walls. Credit: Jeff Moore