Jeff Schmaltz, MODIS Rapid Response Team at NASA GSFC
The plume of ash and steam from the Eyjafjallajokull volcano reached 17,000 to 20,000 feet (5 to 6 kilometers) into the atmosphere on May 10, 2010, when the Moderate Resolution Imaging Spectroradiometer (MODIS) on NASA's Aqua satellite captured this image.
By
OurAmazingPlanet
updated 2/8/2012 12:56:43 PM ET 2012-02-08T17:56:43

Jagged flecks of ash spewed into the air may have boosted the effects of the 2010 eruption of Iceland's Eyjafjallajokull volcano, which paralyzed flights across Europe, a new study finds.

The ash plume from Eyjafjallajokull caused turmoil in the air for nearly a month. Still, the eruption was a relatively small event. For instance, the plume never reached more than about 6 miles (10 kilometers) in height, and the volcano only spewed out about 9.5 billion cubic feet (270 million cubic meters) of ash over the course of several months, while some eruptions can spew out many times more than that in the span of a single day.

The reason that Eyjafjallajokull had such widespread influence was due to how the volcano's ash spread unusually far and stayed for an oddly long time in the atmosphere. To learn more about why this was, a group of scientists collected ash samples from across Iceland.

The researchers found that at Eyjafjallajokull's vent, upwelling magma violently reacted with nearby glacial water. This rapid cooling made the magma contract and fragment into fine, jagged motes of ash. Near the end of the eruption, equally fine, porous ash was generated when small gas bubbles trapped in the molten rock expanded as the magma neared the surface.

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The investigators found that the median width of all the ash grains was less than 1 millimeter wide. Starting about 6 miles (10 km) from the vent and moving outward, particles smaller than 16 microns — about a sixth the width of a human hair — became more than 20 percent of the mix.

Computer models suggest the irregular shapes of these jagged and porous ash grains made them less aerodynamic, increasing how long they spent aloft. This helps explain why a small eruption still impacted a large area.

"This was not a big eruption, but still it caused problems over Europe and the Northern Atlantic," said researcher Piero Dellino, a volcanologist at the University of Bari in Italy. "This means that our complex society is not prepared to face natural hazards. We have to therefore learn from this lesson, considering that other volcanoes in Europe can produce much bigger eruptions — see, for example, historical events of Vesuvius."

Dellino noted that their research took place well after the eruption of Eyjafjallajokull, which might call their findings into question.

"At the moment, it is impossible to monitor in real-time the content and concentration of fine ash in the eruption cloud," he said. "We need to advance science and technology in order to get data as soon as possible after eruption initiation."

The scientists detailed their findings online Jan. 4 in the Journal of Geophysical Research-Solid Earth.

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