Composition ,
Moon and Callisto of dark cratered plains (red) and the
Asgard impact structure (blue), showing the presence of more water ice (
absorption bands from 1 to 2
μm) and less rocky material within Asgard The average
density of Callisto, 1.83 g/cm3, The mass fraction of ices is 49–55%. and possibly
ammonia and various
organic compounds. is darker than the trailing one. This is different from other
Galilean satellites, where the reverse is true. Many fresh
impact craters like
Lofn also show enrichment in carbon dioxide. It was found that Callisto responds to Jupiter's varying background magnetic field like a perfectly
conducting sphere; that is, the field cannot penetrate inside Callisto, suggesting a layer of highly conductive fluid within it with a thickness of at least 10 km. In this case the water-and-ice layer can be as thick as 250–300 km.—0.3549 ± 0.0042—determined during close flybys) suggest that, if Callisto is in
hydrostatic equilibrium, its interior is composed of compressed
rocks and
ices, with the amount of rock increasing with depth due to partial settling of its constituents. In other words, Callisto may be only partially
differentiated. The density and moment of inertia for an equilibrium Callisto are compatible with the existence of a small
silicate core in the center of the planet. The radius of any such core cannot exceed 600 km, and the density may lie between 3.1 and 3.6 g/cm3. However, a 2011 reanalysis of
Galileo data suggests that Callisto is not in hydrostatic equilibrium. In that case, the gravity data may be more consistent with a more thoroughly differentiated Callisto with a hydrated silicate core.
Surface features The ancient surface of Callisto is one of the most heavily
cratered in the Solar System. In fact, the crater density is close to
saturation: any new crater will tend to erase an older one. The large-scale
geology is relatively simple; on Callisto there are no large mountains, volcanoes or other
endogenic tectonic features. The impact craters and multi-ring structures—together with associated
fractures,
scarps and
deposits—are the only large features to be found on the surface. the surrounding terrain. They are possible
cryovolcanic deposits. with a central dome.
Chains of
secondary craters from formation of the more recent crater
Tindr at upper right crosscut the terrain Impact crater diameters seen range from 0.1 km—a limit defined by the
imaging resolution—to over 100 km, not counting the multi-ring structures. The second largest is
Asgard, measuring about 1,600 km in diameter. The most likely candidate process is the slow
sublimation of ice, which is enabled by a temperature of up to 165
K, reached at a subsolar point. Absolute dating has not been carried out, but based on theoretical considerations, the cratered plains are thought to be ~4.5
billion years old, dating back almost to the formation of the
Solar System. The ages of multi-ring structures and impact craters depend on chosen background cratering rates and are estimated by different authors to vary between 1 and 4 billion years. and probably oxygen. It was detected by the
Galileo Near Infrared Mapping Spectrometer (NIMS) from its absorption feature near the wavelength 4.2
micrometers. The surface pressure is estimated to be 7.5 pico
bar (0.75
μPa) and particle density 4 cm−3. Because such a thin atmosphere would be lost in only about four years though
atmospheric escape, it must be constantly replenished, possibly by slow sublimation of carbon dioxide ice from Callisto's icy crust, its high electron density of 7–17 cm−3 cannot be explained by the photoionization of the atmospheric
carbon dioxide alone. Hence, it is suspected that the atmosphere of Callisto is actually dominated by
molecular oxygen (in amounts 10–100 times greater than ). However,
oxygen has not yet been directly detected in the atmosphere of Callisto. Observations with the
Hubble Space Telescope (HST) placed an upper limit on its possible concentration in the atmosphere, based on lack of detection, which is still compatible with the ionospheric measurements. At the same time, HST was able to detect
condensed oxygen trapped on the surface of Callisto. Atomic hydrogen has also been detected in Callisto's atmosphere via analysis of 2001 Hubble Space Telescope data. Spectral images taken on 15 and 24 December 2001 were re-examined, revealing a faint signal of scattered light that indicates a hydrogen corona. The observed brightness from the scattered sunlight in Callisto's hydrogen corona is approximately two times larger when the leading hemisphere is observed. This asymmetry may originate from a different hydrogen abundance in both the leading and trailing hemispheres. However, this hemispheric difference in Callisto's hydrogen corona brightness is likely to originate from the extinction of the signal in Earth's
geocorona, which is greater when the trailing hemisphere is observed. ==Origin and evolution==