Video footage of Iceland’s 2010 Eyjafjallajökull eruption is providing researchers from the University of Cambridge with rare, up-close observations of volcanic ash clouds — information that could help better forecast how far explosive eruptions disperse their hazardous ash particles.
When Eyjafjallajökull erupted in 2010, it ejected roughly 250 million tonnes of volcanic ash into the atmosphere: much of which was blown over Europe and into flight paths. With planes grounded, millions of air passengers were left stranded.
Forecasts of how ash will spread in the aftermath of an explosive eruption can help reduce impacts to aviation by informing decisions to shutdown areas of airspace. But these forecasts require knowledge of what is happening at the volcano, information that often can’t be obtained directly and must instead be estimated.
In the new study, the researchers split the 17-minute film into time-segments to understand how the Eyjafjallajökull ash cloud grew upwards and outwards as the eruption ensued.
“No one has previously observed the shape and speed of wind-blown ash clouds directly,” said Professor Andy Woods, lead author of the study, from Cambridge’s Department of Earth Sciences and Institute for Energy and Environmental Flows. The new video analysis method was reported in Nature Communications Earth and Environment.
By comparing characteristics of the ash cloud, such as its shape and speed, at time intervals through the video, the researchers were able to calculate the amount of ash spewed from the volcano.
That rate of ash flow (called eruption rate) is an important metric for forecasting ash cloud extent, said Woods. “The eruption rate determines how much ash goes up into the atmosphere, how high the ash cloud will go, how long the plume will stay buoyant, how quickly the ash will start falling to the ground and the area over which ash will land.”
Generally, the higher the ash plume, the wider the ash will be dispersed, and the smaller the ash particles are, the longer they stay buoyant. This dispersal can also depend on weather conditions, particularly the wind direction.
Volcanoes across the world are increasingly monitored via video, using webcams or high-resolution cameras. Woods thinks that, if high-frame rate video observations can be accessed during eruption, then this real-time information could be fed into ash cloud forecasts that more realistically reflect changing eruption conditions.
During the 17-minute footage of the Eyjafjallajökull, they observed that the eruption rate dropped by about half. “It’s amazing that you can learn eruption rate from a video, that’s something that we’ve previously only been able to calculate after an eruption has happened,” said Woods. “It’s important to know the changing eruption rate because that could impact the ash cloud dispersal downwind,” he added.
It’s usually extremely challenging for volcanologists to take continuous measurements of ash clouds whilst an eruption is happening. "Instead, much of our understanding of how ash clouds spread in the atmosphere is based on scaled-down lab models,” said Dr Nicola Mingotti, a researcher in Woods’ group and co-author of this study. These experiments are performed in water tanks, by releasing particle-laden or dyed saline solutions and analysing footage of the plume as it dissipates.
Woods and his collaborators have been running lab experiments like these for several years, most recently trying to understand how eruption plumes are dragged along by the wind. It’s a big bonus to have video measurements from a real eruption, said Woods, and reassuringly, the real observations agree closely with what they’ve been observing in the lab. “Demonstrating our lab experiments are realistic is really important, both for making sure we understand how ash plumes work and that we forecast their movements effectively.”
Mingotti, N., & Woods, A. W. (2024). Video-based measurements of the entrainment, speed and mass flux in a wind-blown eruption column. Communications Earth & Environment, 5(1), 237.
The video was first published here, under the attribution CC BY 4.0, with credit to: Manzella, I., Bonadonna, C., Phillips, J. C., & Monnard, H. (2024, March 20). Volcanic plume recorded during the eruption of Eyjafjallajökull (Iceland) in 4 May 2010. Zenodo. https://doi.org/10.5281/zenodo.10842769
Feature image: Eruption atEyjafjallajökullApril 17, 2010. Árni Friðriksson / Wikimedia Commons.
