CHAPTER 23 | COMPARATIVE PLANETOLOGY OF JUPITER AND SATURN 513
proved mathematically that solid rings would be unstable.
Saturn’s rings, he concluded, had to be made of separated par-
ticles. In 1867, Daniel Kirkwood demonstrated that gaps in the
rings were caused by resonances with some of Saturn’s moons.
Spectra of the rings eventually showed that the particles were
mostly water ice.
Study The Rings of Saturn on pages 514–515 and
notice three points and a new term:
Th e rings are made up of billions of ice particles, each in its
own orbit around the planet. But, just as for Jupiter’s rings,
the particles observed now in Saturn’s rings can’t have been
there since the planet formed. Th e rings must be replenished
now and then by impacts on Saturn’s icy moons or by the
disruption of a small moon that moves too close to the
planet.
Th e gravitational eff ects of small moons called shepherd satel-
lites can confi ne some rings in narrow strands or keep the
edges of rings sharp. Moons can also produce waves in the
rings that are visible as tightly wound ringlets.Th e ring particles are confi ned to a thin layer in Saturn’s
equatorial plane by the gravity of small moons. Th e small
moons in turn are controlled by gravitational interactions
with larger, more distant moons. Th e rings of Saturn, and
the rings of the other Jovian worlds, are created from and1
2
3
controlled by the planet’s moons. Without the moons, there
would be no rings.
Modern astronomers fi nd simple gravitational interactions pro-
ducing even more complex processes in the rings. Where particles
orbit in resonance with a moon, the moon’s gravity triggers spiral
density waves in much the same way that spiral arms are produced
in galaxies. Th e spiral density waves spread outward through the
rings. If the moon follows an orbit that is inclined to the ring
plane, the moon’s gravity causes a diff erent kind of wave—spiral
bending waves—ripples extending above and below the ring
plane, which spread inward. Both of these kinds of processes are
shown in the inset ring image on page 515.
Many other processes occur in the rings. Specks of dust
become electrically charged by sunlight, and Saturn’s magnetic
fi eld lifts them out of the ring plane. Small moonlets embedded
in the rings produce gaps, waves, and scallops in the rings. Th e
Cassini spacecraft has recorded dramatic images (■ Figure 23-16)
of the Saturn ring system, including two faint outer rings (E and
G) that are rarely detectable from Earth, and these also appear to
be related to moons.
Th e word “particle” in colloquial language connotes tiny specks,
but in the context of Saturn’s rings, astronomers use that term to
refer to any object from snowlike powder grains up to building-sized
icy mini-moons (look again at page 514). Th e larger objects are
understood to be aggregates of the smaller ones. Th e subtle colors of■ Figure 23-16
The Cassini spacecraft recorded this image as it passed through Saturn’s shadow. Earth is visible as a faint blue dot just inside the G ring,
and jets of ice particles vented from the moon Enceladus are visible at the left extreme of the larger E ring. Two faint rings associated
with small moons were discovered in this image. (NASA/JPL/Space Science Institute)
Visual-wavelength imageEnceladusEarth