Published time: January 06, 2014 19:22                                                                             

 

Yellowstone National Park in Wyoming.(AFP Photo / Karen Bleier)

Scientists have discovered what causes cataclysm-inducing supervolcanoes to erupt, and the answer offers little reassurance. Their eruptions are caused by magma buoyancy, which makes them less predictable and more frequent than previously thought.

A team of geologists from the Swiss Federal Institute of  Technology in Zurich (ETH) modeled a supervolcano – such as  Yellowstone in Wyoming – using synthetic magma heated up with a  high-energy X-ray to see what could create a powerful discharge.  A separate international team, led by Luca Caricchi of the  University of Geneva, conducted more than 1.2 million computer  simulations of eruptions.

Both groups have arrived at similar conclusions, with two studies simultaneously published in Nature  Geoscience magazine.

“We knew the clock was ticking but we didn’t know how fast:  what would it take to trigger a super-eruption?” said Wim  Malfait, the lead author of the ETH study.

“Now we know you don’t need any extra factor – a supervolcano  can erupt due to its enormous size alone.”

It was previously thought that supervolcanoes – which spew out  hundreds more times of lava and ash than ordinary ruptures –   could be triggered by earthquakes or other outside tectonic  phenomena.

It was also clear that these volcanoes do not operate like  ordinary eruptions, which rely on magma filling their chambers,  and spurting through an opening, once the pressure gets to a  certain point, since the chambers of supervolcanoes are too large  to be over pressurized to the same degree.

Now, the studies have identified the unique supervolcano  mechanism that makes their discharge more like powerful  explosions than normal eruptions.

The molten magma in the mostly underground supervolcano is  lighter than the surrounding rocks, and the difference in  pressure, creates a ‘buoyancy effect’, meaning the super-hot  terrestrial soup is always attempting to burst out.

“The difference in density between the molten magma in the  caldera and the surrounding rock is big enough to drive the magma  from the chamber to the surface,” said Jean-Philippe  Perrillat of the National Centre for Scientific Research in  Grenoble, where the experiments were conducted.

 

Artist’s impression of the magma chamber of a supervolcano with partially molten magma at the top. (ESRF/Nigel Hawtin)

“The effect is like the extra buoyancy of a football when it  is filled with air underwater, which forces it to the surface  because of the denser water around it. If the volume of magma is  big enough, it should come to the surface and explode like a  champagne bottle being uncorked.”

The researchers believe that the pressure force of the molten  magma pools can be strong enough to crack 10 km thick layers of  rock, before spewing out a maximum of between 3,500 and 7,000  cubic kilometers of lava. In comparison, the notorious Krakatoa  explosion in 1883 likely ejected less than 30 cubic kilometers of  debris into the atmosphere.

The effects on Earth are likely to be fundamental, with previous   studies suggesting that such a supervolcano  could decrease the temperature on Earth by 10 C for a decade, as  the ash would prevent sunlight from reaching the ground.

The last supervolcano eruption in Lake Toba took place more than  70,000 years ago. According to one highly-contested theory it may  have wiped out more than half of the planet’s population; in any  case the effect on the world would be dramatic.

“This is something that, as a species, we will eventually  have to deal with. It will happen in future,” said Dr  Malfait.

“You could compare it to an asteroid impact – the risk at any  given time is small, but when it happens the consequences will be  catastrophic.”

A volcano has to eject more than 1,000 cubic km of debris in a  single eruption to be counted as a supervolcano, and there are  less than ten potential sites with sufficiently large magma  chambers around the world, though there may be others lurking  underneath the ocean surface. These formations, which are more  often flat with no outlet, are expected to erupt once every  50,000 years, though there is no regularity to the frequency of  eruptions.

The computer modelers believe that the buoyancy mechanism means  that such eruptions occur more frequently than previously  thought, though the exact extent is hard to estimate without  studying magma flows at each potential location.

Nonetheless, the ETH scientists say that there could be  detectable pressure changes, and perhaps even spectacular rises  of ground level sometime before the eventual explosion. But it is  not clear how long after such changes an eruption would take  place, or whether advance knowledge would actually help to  mitigate its impact.

http://rt.com/news/supervolcano-buoyancy-yellowstone-eruption-237/

Categories: Hmmm?

Tags: Supervolcano, supervolcanoes