432 Encyclopedia of the Solar System
FIGURE 1 Global view of Europa’s trailing hemisphere,
acquired early in theGalileospacecraft’s tour of the jovian
system. The colors in this image have been enhanced to show
detail. This image shows the extent of the reddish-brown
material that mottles Europa’s surface, along with numerous
linear features, many of them over 1000 km in length. Two large
impact craters are also visible: Pwyll, surrounded by bright rays,
is thought to be the youngest crater on Europa, and Callanish is
the large circular feature toward the west. (NASA/JPL.)
Such intriguing findings meant there was much anticipa-
tion for theGalileomission, which launched from the Space
ShuttleAtlantisin 1989 and entered orbit around Jupiter
in 1995. The primary mission included dropping a probe
into Jupiter’s atmosphere, as well as observations of all the
satellites and Jupiter’s atmosphere and local environment.
Despite severe data rate limitations during the mission (be-
cause the spacecraft’s main antenna did not open), the data
fromGalileowere so intriguing that the mission was ex-
tended in 1997 for a further 3 years, in order to make 8
further close flybys of Europa, and also to study its volcani-
cally active neighbor, Io. Data from the extendedGalileo
Europa Mission afforded many more high-resolution im-
ages of Europa, as well as magnetic data that strongly imply
the presence of a briny layer beneath the surface today.
The physical and orbital properties of Europa are sum-
marized in Table 1.2. Formational and Compositional Models
During the formation of our solar system, the growing gas
giant planet Jupiter pulled material from the solar nebula. It
is now understood that, in contrast to early models of satel-
liteaccretion, the solids of the Joviansubnebulawere
probably grabbed from the solar nebula in nearly primor-
dial form, and that the subnebula may have been gas-poor.
Thus, the material incorporated into the Galilean satellites
was probably similar in composition to the asteroids of the
outer asteroid belt, containing ice,anhydrous silicates,
carbonaceousmaterial, and nickel–iron metal alloy.
The Galilean satellites formed by aggregation of these
solids, with the proportion of ice varying with distance from
the warm protoplanet Jupiter. Io formed relatively close to
Jupiter, so it was not able to accrete and retain significant
amounts of water ice. As the next moon outward, Europa
formed as a mostly rocky satellite (density=3.0), able to
accrete sufficient volatiles to form a∼100 km thick outer
layer of H 2 O. In the colder reaches of the jovian subnebula,
Ganymede and Callisto formed with near-equal amountsTABLE 1 Properties of EuropaDiscovered 1610Discoverers Galileo Galilei, Simon Marius
Mean distance from Jupiter 671,100 km
Radius 1560. 8 ± 0 .5km
Mass (4. 8017 ± 0 .000014)× 1022 kg
Density 3. 014 ± 0 .005 g/cm^3
Orbital period 85 hours (3.551 Earth days)
Rotational period 85 hours (3.551 Earth days)
Orbital eccentricity 0.0094
Orbital inclination 0.469°
Visual geometric albedo 0.68
Escape velocity 2.026 km/s
Spacecraft visitors Voyager 1(March 1979)
Voyager 2(July 1979)
Galileo(July 1994 to 2000)
Predicted average surface Temperature ∼50K (poles) to∼110K (equator)