Studying Saturn's Super Storm
The ground-based observations were made by the Very Large Telescope of the European Southern Observatory in Chile, and NASA’s Infrared Telescope Facility at the summit of Mauna Kea in Hawaii.
The vivid cloud structures that wreaked havoc across wide swathes of the mid-northern latitudes of Saturn’s atmosphere captured the imaginations of amateur and professional astronomers alike, from its first appearance in December 2010 through much of 2011.
But in new reports that focus on the temperatures, winds and composition of Saturn’s atmosphere, scientists find that the spectacular cloud displays were only part of the story.
Much of the associated activity took place beyond the reach of visible-light cameras, and the after-effects are still continuing today.
“It’s extremely unusual, as we can only see the vortex at infrared wavelengths -- we can’t tell that it is there simply by looking at the cloud cover.”
As the visible storm erupted in the roiling cloud deck of Saturn’s troposphere, waves of energy rippled hundreds of kilometers upwards, depositing their energy as two vast ‘beacons’ of hot air in the stratosphere.
The beacons were expected to cool down and dissipate, but by late April 2011 -- by which time bright cloud material had encircled the entire planet -- the hot spots had merged to create an enormous vortex that for a brief period exceeded even the size of Jupiter’s famous Great Red Spot.
Furthermore, the temperature of the vortex was far higher than expected, some 80 degrees C warmer than the surrounding atmosphere. At the same time, huge spikes in the amount of gases like ethylene and acetylene were detected.
“But Jupiter’s vortex is embedded deep down in the turbulent ‘weather zone’, whereas the vast vortex on Saturn is higher up in the atmosphere where, normally, you wouldn’t expect anything like it to have formed,” says Dr. Fletcher.
“Although there are parallels to be drawn between the two, the mechanisms by which they were formed and the length of time they are going to exist seem to be very different.”
Jupiter’s famous vortex has raged for at least 300 years, but after traversing the planet once every 120 days since May 2011, Saturn’s large beacon is cooling and shrinking. Scientists expect it to fade away completely by the end of 2013.
The question now remains as to whether Saturn’s storm-generating energy has been sapped or if there will be a repeat performance.
The outburst already caught observers by surprise by arriving during the planet’s northern hemisphere spring, years ahead of the predictably stormy summer season.
“The beauty is that Cassini will be operating until the Saturn system reaches its summer solstice in 2017, so if there is another global event like this, we’ll be there to see it,” says ESA’s Cassini project scientist Nicolas Altobelli.
Saturn is not a world expected to host life, but studying Saturn can help astronomers understand how giant planets form and evolve. This information is valuable in interpreting observations of exoplanets around distant stars. Studying Saturn can also yield clues about the local environment of giant, gaseous planets and their potential to host potentially habitable moons.