Despite more than a decade of winter darkness, Saturn’s north pole is home to an unexpected hot spot remarkably similar to one at the planet’s sunny south pole. The source of its heat is a mystery. Now, the first detailed views of the gas giant’s high latitudes from the Cassini spacecraft reveal a matched set of hot cyclonic vortices, one at each pole.
While scientists already knew about the hot spot at Saturn’s south pole from previous observations by the W. M. Keck Observatory in Hawaii, the north pole vortex was a surprise.
“We had speculated that the south pole hot spot was connected to the southern, sunlit conditions,” says Glenn Orton, a senior research scientist at NASA’s Jet Propulsion Laboratory, Pasadena, California, and co-investigator on Cassini’s composite infrared spectrometer. “Since the north pole has been deprived of sunlight since the arrival of winter in 1995, we didn’t expect to find a similar feature there.”
The infrared data show that the shadowed north pole vortex shares much the same structure and temperature as the one at the sunny south pole. The cores of both show a depletion of phospine gas, an imbalance probably caused by air moving downward into the lowest part of Saturn’s atmosphere, the troposphere. Both polar vortices appear to be long-lasting and intrinsic parts of Saturn and are not related to the amount of sunlight received by one pole or the other.
“The hot spots are the result of air moving polewards, being compressed and heated up as it descends over the poles into the depths of Saturn,” says Leigh Fletcher, a planetary scientist from the University of Oxford, England, and lead author of the paper. “The driving forces behind the motion, and indeed the global motion of Saturn’s atmosphere, still need to be understood.”
Though similar, the two polar regions differ in one striking way. At the north pole, the newly discovered vortex is framed by the distinctive, long-lived and still unexplained polar hexagon. This mysterious feature encompassing the entire north pole was first spotted in the 1980s by NASA’s Voyager 1 and 2 spacecraft. Cassini’s infrared cameras also detected the hexagon in deep atmospheric clouds early in 2007.
In their paper, Fletcher and his colleagues report that the bright, warm hexagon is much higher than previous studies had shown. “It extends right to the top of the troposphere,” says Fletcher. “It is associated with downward motion in the troposphere, though the cause of the hexagonal structure requires further study.”
Winter lasts about 15 years on Saturn. Researchers anticipate that when the seasons change in the coming years and Saturn’s north pole is once again in sunlight, they will be able to see a swirling vortex with high eye walls and dark central clouds like the one now visible at the south pole. “But Saturn may surprise us again,” says Fletcher.
“The fact that Neptune shows a similar south polar hot spot whets our appetite for the strange dynamics of the poles of the other gas giants,” Fletcher says.
More information about Jupiter’s poles will come from NASA’s Juno mission, currently scheduled for launch in 2011 and arrival in 2016.