Supereruptions can be primed in decades.
In the first part (http://tinyurl.com/p88v7vq) we discussed how volcanoes can be filled with magma directly from the mantle over a short period of time. Here we discuss a similar process in supervolcanoes. Supervolcanoes produce devastating eruptions that have regional effects such as covering large areas in metres of burning ash, as well as global effects on climate. The last supereurption, that of Toba in Indonesia, occurred around 70,000 years ago is thought to have reduced the global human population to less than 5,000, as evidenced by a genetic bottleneck. Over 2,500 cubic kilometres of rock were violently ejected onto the Earth's surface, producing metres deep layers of ash as far away as India. For comparison, Krakatoa's explosion produced about 12 cubic Km.
Santorini erupted more recently in the Bronze age 3500 years ago, with powerful impacts on nascent Mediterranean civilisations (though only 60 cubic Km of rock flew out). Though this island is small by supervolcano standards, it remains the most recent large scale eruption of silica rich magma available for study, and shares similar processes with its larger cousins. As the magma chamber emptied its roof collapsed like a piston, taking most of the island down with it and generating a large tsunami. The small island in the centre of the caldera is an emergent lava dome from renewed activity deep below.
Modern geologists have never witnessed a catastrophic supereruption, since the rest period between explosions is long (18,000 years between Santorini's last two blowouts). Geophysical data from currently simmering examples such as Yellowstone and Campi Flegrei near Naples has proved hard to interpret. Researchers are therefore using geochemistry in order to understand how these enormous explosions developed in the past, and published a paper in Nature last year. They hope to use this knowledge in assessing volcanic hazards at active supervolcanoes worldwide and to develop understanding of the pre-eruptive phase of these powerful beasts.
The team analysed the diffusion of elements such as titanium through crystals of alkali feldspar in the lava from Santorini, hoping to learn about its journey from the mantle. Lavas tend to stop and stew in their own juices on the way up, especially felsic (silica rich) ones. They were shocked to discover that rather than the expected thousands of years, the magma only took about a century to rise from mantle to surface. They also showed that large changes in magma composition can happen very quickly. The chamber was recharged from below as expected, different magmas were stewing and mixing, but all in a much shorter time frame than expected.
This has obvious implications for monitoring and prediction at the world's dozen or so known supervolcanoes. Deep movements of magma are now clearly a priority target for monitoring, and will be betrayed by the earthquakes they cause. However, we need to be listening in order to make use of the warning they provide. Many volcanoes in the Andes for example are poorly monitored, and a large, sudden eruption in a remote area could impact the world's climate and affect us all
Loz
Santorini Caldera image credit: SOKOBAN/Wikimedia Commons
http://www.livescience.com/31111-super-volcano-eruption-prediction.html
http://whyfiles.org/2012/reading-magma-predicting-giant-eruptions/
paywall access: http://www.nature.com/nature/journal/v482/n7383/full/nature10706.html











