Think our weather is bad? Trapped water on Saturn can trigger violent SUPERSTORMS that snake around the entire planet


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Once every 20 or 30 years, a superstorm greater than any on Earth breaks out on Saturn and whips around the planet in a violent spectacle that rages for months on end.

Dubbed 'Great White Spots' after the tinge of their lightning-laced brew, the outbursts are so large they can be witnessed by telescopes from Earth. 

Now a team claims the extraordinary behaviour of water vapour in the gas giant's atmosphere could be the reason why these storms happen so infrequently. 

Once every 20 or 30 years, a superstorm greater than Earth breaks out on Saturn and whips around the ringed planet in a violent spectacle that rages for months on end. Dubbed 'Great White Spots', the outbursts are so large they can be witnessed by telescopes from Earth. The are seen here in the northern part of the planet

Once every 20 or 30 years, a superstorm greater than Earth breaks out on Saturn and whips around the ringed planet in a violent spectacle that rages for months on end. Dubbed 'Great White Spots', the outbursts are so large they can be witnessed by telescopes from Earth. The are seen here in the northern part of the planet

SATURN'S GREAT WHITE SPOTS 

The Great White Spots, also known as Great White Oval, describe periodic storms on Saturn that can be seen by telescope from Earth. 

In 140 years of telescope observations, great storms have erupted on Saturn six times. They can encircle the entire planet which has a average radius of 36,184 miles (58,232 km).

Cassini and observers on Earth tracked the most recent of these storms from December 2010 to August 2011.

During that time, the storm exploded through the clouds, eventually winding its way around Saturn 

In the last century and a half, astronomers have observed six of these titanic events. 

As on Earth, Saturn's atmosphere consists of different layers, explain Cheng Li and Andrew Ingersoll of the California Institute of Technology.

For most of the time, the outer layer where clouds form is less dense than the sub-cloud layer that stretches all the way down to the center of the gassy planet.

Like oil floating on water, the less dense outer layer rests on top of a denser air mix of mainly hydrogen and helium, but also water molecules.

In Saturn's case, the outer layer prevents the warmer air underneath from rising, cooling and condensing - the process required to create thunderstorms.

This state of affairs lasts for decades at a time.

During the very long calm before the storm, the outer atmosphere radiates heat into space and progressively cools until finally it becomes more dense then the lower layer.

The balance between the layers becomes disrupted, and the warm air that had been kettled up below punches its way outward.

The heavier water molecules in the roiling mix are then shed in massive storms until the original balance is restored, and calm returns.

This false-colour image from the Cassini spacecraft reveal one of these superstorms in detail. Clouds that appear blue here are the highest and are semitransparent. Those that are yellow and white are thick clouds at high altitudes. Those shown green are intermediate clouds. Red and brown colors are clouds at low altitude

This false-colour image from the Cassini spacecraft reveal one of these superstorms in detail. Clouds that appear blue here are the highest and are semitransparent. Those that are yellow and white are thick clouds at high altitudes. Those shown green are intermediate clouds. Red and brown colors are clouds at low altitude

The two scientists tested their theory by developing simulation software similar to that used for weather forecasting on Earth, and compared the results to observations of the Cassini spacecraft orbiting Saturn.

'The time scale depends on how fast the planet can cool by radiating heat into space,' Li said.

'Because Saturn has a massive atmosphere, it takes decades to cool.'

Saturn and its gas giant neighbor Jupiter both sport massive storms. 

But rather than giant thunderstorms, the rain that falls in Jupiter's 'Great Red Spot' is more similar to an Earthly drizzle, said Li.

This is likely because Saturn has more water that can condense to form clouds than Jupiter.

This series of images from Nasa's Cassini spacecraft shows the development of the largest storm seen on the planet since 1990. These images chronicle the storm from its start in late 2010 through mid-2011, showing how the distinct head of the storm quickly grew large but eventually became engulfed by the storm's tail

This series of images from Nasa's Cassini spacecraft shows the development of the largest storm seen on the planet since 1990. These images chronicle the storm from its start in late 2010 through mid-2011, showing how the distinct head of the storm quickly grew large but eventually became engulfed by the storm's tail




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