|
Giant
Storm Eruption at Jupiter Unearths a Buried Past
January 24, 2008
Internal
Heat Drives Jupiter's Giant Storm Eruption
(each
image contains a HOT SPOT to a
individual Hi-Res Image)
More
Information ROLLOVER
|
Credit:
NASA, ESA, IRTF, and A. Sánchez-Lavega and R. Hueso
(Universidad del País Vasco, Spain )
Scientists
around the globe have observed an astonishing and rare change in
Jupiter's atmosphere -- a huge disturbance churning in the middle
northern latitudes of the planet as two giant storms erupted.
Jupiter's winds are the strongest at middle northern
latitudes, reaching about 600 kilometers per hour (370 miles per
hour). Similar phenomena occurred in 1975 and 1990, but this
event has never been observed before with high-resolution modern
telescopes.
The storm eruption was captured in late March
2007 by NASA's Hubble Space Telescope, the NASA Infrared
Telescope Facility in Hawaii and telescopes in the Canary Islands
(Spain). A network of smaller telescopes around the world also
supported these observations.
An international team
coordinated by Agustín Sánchez-Lavega from the
Universidad del País Vasco in Spain presents their
findings about this event in the January 24 issue of the journal
Nature. The team monitored the new eruption of cloud activity and
its evolution with unprecedented resolution.
"Fortuitously,
we captured the onset of the disturbance with Hubble, while
monitoring the planet to support the New Horizons flyby
observations of Jupiter in its route to Pluto. We saw the storm
grow rapidly since its beginning, from about 400 kilometers [250
miles] to more than 2,000 kilometers [1,245 miles] in size in
less than one day," said Sánchez-Lavega.
The
atmosphere of the gaseous giant planet Jupiter is always
turbulent. Its circulation is dominated by a pattern of cloud
bands alternating with latitude, and by a persistent system of
jet streams, both of unknown origin. Changes in the cloud bands
are sometimes violent, starting from a localized eruption and
followed by the development of a planetary-scale disturbance. The
nature of these disturbances and the power source for these jets
remains a controversial matter among planetary scientists and
meteorologists. The phenomena could be powered by the sun, as is
Earth, by the strong internal heat source emanating from
Jupiter's interior, or by a combination of both.
According
to the analysis, the bright plumes were storm systems triggered
in Jupiter's deep water clouds that vigorously moved upward in
the atmosphere and injected a fresh mixture of ammonia ice and
water about 30 kilometers (20 miles) above the visible clouds.
The storms moved in the peak of a jet stream in Jupiter's
atmosphere at 600 kilometers per hour (375 miles per hour). They
disturbed the jet and formed in their wake a turbulent
planetary-scale disturbance containing red cloud particles.
"The infrared images distinguish the plumes from
lower-altitude clouds and show that the plumes are lofting ice
particles higher than anyplace else on the planet," said
Glenn Orton of NASA's Jet Propulsion Laboratory, Pasadena, Calif.
Orton is second author of the paper.
In spite of the
energy deposited and the stirring and turmoil generated by the
storms, the jet remained practically unchanged when the
disturbance ceased, keeping steady against these storms. Models
of the disturbance indicate that the jet stream extends deep in
the buried atmosphere of Jupiter, more than 100 kilometers (62
miles) below the cloud tops where most sunlight is absorbed.
"This confirms previous findings by the Galileo
probe when it descended through Jupiter's upper atmosphere in
December 1995. Although both regions are meteorologically
different, all the evidence points to a deep extent for Jupiter's
jets and suggest that the internal heat power source plays a
significant role in generating the jet," said
Sánchez-Lavega.
A comparison of this disturbance
with the two previous events in 1975 and 1990 shows surprising
similarities and coincidences, all of which remain unexplained.
All three eruptions occurred with a periodic interval of about 15
to 17 years. The plumes always appear in the jet peak; the
disturbance erupted with exactly two plumes. Finally, the plumes
moved with the same speed of the jet peak in all three events.
Understanding this outbreak could be the key to unlocking the
mysteries buried in the deep Jovian atmosphere.
Understanding
these phenomena is important for Earth's meteorology, where
storms are present everywhere and jet streams dominate the
atmospheric circulation. In this way, Jupiter represents a
natural laboratory where atmospheric scientists study the nature
and interplay of the intense jets and severe atmospheric
phenomena.
JPL is managed for NASA by the California
Institute of Technology. The Hubble Space Telescope is a project
of international cooperation between NASA and the European Space
Agency.
Source:
NASA / JPL
|
Scientific
Frontline®
The
Comm Center
Space
Weather Alerts
Stellar
Nights®
The
E.A.R.®
World
Report News
Photo,
Sketches, & Video Gallery
|
