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Saturn's
Giant Sponge
Tuesday, February 5, 2008
This
is a false-color image of jets (blue areas) in the southern
hemisphere of Enceladus taken with the Cassini spacecraft
narrow-angle camera on Nov. 27, 2005. It has been processed
to reveal the individual jets that comprise the plume.
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Enceladus
is seen here as a white disk across the unilluminated side
of Saturn's rings (black and white stripes across the bottom
of the image). This image was taken with the Cassini
spacecraft narrow-angle camera on Oct. 27, 2007.
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Credit:
NASA/JPL/Space Science Institute
One of Saturn's rings does
housecleaning, soaking up material gushing from the fountains on
Saturn's tiny ice moon Enceladus, according to new observations
from the Cassini spacecraft.
"Saturn's A-ring and
Enceladus are separated by 100,000 kilometers (62,000 miles), yet
there’s a physical connection between the two," says
Dr. William Farrell of NASA's Goddard Space Flight Center in
Greenbelt, Md. "Prior to Cassini, it was believed that the
two bodies were separate and distinct entities, but Cassini’s
unique observations indicate that Enceladus is actually
delivering a portion of its mass directly to the outer edge of
the A-ring." Farrell is lead author of a paper on this
discovery that appeared in Geophysical Research Letters January
23.
This is the latest surprising phenomenon associated
with the ice geysers of Enceladus to be discovered or confirmed
by Cassini scientists. Earlier, the geysers were found to be
responsible for the content of the E-ring. Next, the whole
magnetic environment of Saturn was found to be weighed down by
the material spewing from Enceladus, which becomes plasma -- a
gas of electrically charged particles. Now, Cassini scientists
confirm that the plasma, which creates a donut-shaped cloud
around Saturn, is being snatched by Saturn’s A-ring, which
acts like a giant sponge where the plasma is absorbed.
Shot
from Enceladus’ interior, the gas particles become
electrically charged (ionized) by sunlight and collisions with
other atoms and electrons. Once electrically charged, the
particles feel magnetic force and are swept into the space around
Saturn dominated by the planet's powerful magnetic field. There,
they are trapped by Saturn’s magnetic field lines, bouncing
back and forth from pole-to-pole. The fun ends, however, if their
bouncing path carries them inward toward Saturn to the A-ring.
There they stick, in essence becoming part of the ring. "Once
they get to the outer A-ring, they are stuck," says
Farrell.
"This is an example of how Saturn’s
rings mitigate the overall radiation environment around the
planet, sponging up low- and high-energy particles," says
Farrell. By contrast, Jupiter has no dense rings to soak up
high-energy particles, so that planet’s extremely high
radiation environment persists.
The Cassini observations
confirm a prediction by Dr. John Richardson and Dr. Slobodan
Jurac of the Massachusetts Institute of Technology. In the early
1990’s, Hubble Space Telescope observations revealed the
presence of a large body of water-related molecules in orbit
about 240,000 km (almost 150,000 miles) from the planet.
Richardson and Jurac modeled this water cloud and demonstrated it
could migrate inward to the A-ring. "We relied on their
predictions to help us interpret our data," said Farrell.
"They predicted it, and we were seeing it."
Data
for the discovery that Saturn's A-ring acts like a sponge were
collected in July 2004 when Cassini arrived in orbit around
Saturn, making its closest flyby over the A-ring. "We
skimmed over the top of that ring fairly close," said
Farrell.
Hot spots on the inside wall of the plasma donut
-- the part colliding with the A-ring -- were emitting radio
signals. These signals behaved as a sort of natural radio beacon,
indicating the local plasma density at the inner edge of the
donut. The signals were detected by Cassini's Radio and Plasma
Wave instrument. The team used these signals to monitor the
density of the plasma (the higher the frequency, the greater the
density) and hence witness the change in gas density with
time.
"As we approached the A-ring, the frequency
dropped, implying that the plasma density was going down because
it was being absorbed by the ring," said Farrell. "What
really drove this home was what happened to the signal when we
passed over a gap in the rings, called the Cassini division.
There, the frequency went higher, implying that the plasma
density was going up because plasma was leaking through the
gap."
The research was funded by NASA through the
Cassini-Huygens project. Cassini-Huygens is an international
collaboration among NASA, the European Space Agency, and the
Italian Space Agency. The Cassini orbiter was built and is
managed by NASA's Jet Propulsion Laboratory, Pasadena, Calif.
Source:
NASA / JPL
Permalink:
http://www.sflorg.com/cassini/missionnews/casmn020508_01.html
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