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Concession: I could not figure out how to change the font size for the Wiki Page and thus I apologize if my image captions are difficult to spot.

I will simulate the research the 2010 eruption of the Icelandic volcano Eyjafjallajokull in order to simulate its ash dispersal from Eyjafjallajokull using HYSPLIT. By simulating the ash dispersal during different times in of the year I hope to determine how the ash dispersal variation given varies with different atmospheric circulation patternscirculation patterns–both by season and by week. 

Eyjafjallajokull Background Info

Despite its moderate ranking on the VEI (Volcanic Explosively Index) given its max plume height and magma discharge, Eyjafjallajokull caused significant ash dispersal. 80% of the erupted material comprised of airborne ash, and the ash dispersed over an area of approximately 7 million km^2 in Europe and the North Atlantic. While 50% of the ash fell in Iceland, .02% reached mainland Europe. 

The ash caused great trouble to Europe and led to the closure of UK airspace from April 15th through 20th, for finer ash particles clogged airplane engines. 

Plume Height

Image 1: Shows the plume height of the ash from the Eyjafjallajokul eruption. The average plume height is 7.3 km (approximately 2/3rds of the height of the troposphere). 

While the plume height ranged from 3 to 10 km, we will simulate Eyjafjallajokul using its average plume height of 7.3 km. 

Source: NASA, https://www.nasa.gov/topics/earth/features/iceland-volcano-plume-archive1.html

Ash Dispersal

Image 2: Shows the ash dispersal from Eyjafjallajokul on April 19th, 2010. The ash went so far as to reach mainland Europe and cover a significant portion of the United Kingdom. 

Source: NASA, https://www.nasa.gov/topics/earth/features/iceland-volcano-plume-archive1.html

HYSPLIT Simulations for Eyjafjallajokull (Varying Eruption Date)

By simulating Eyjafjallajokull for various eruption dates, I sought to investigate how the circulation patterns changed both seasonally and weekly and whether the seasonal versus weakly variations dominated the ash dispersal patterns. Simulations showed that the weekly changes in atmospheric circulation patterns dominated any seasonal trends. Eyjafjallajokull sits at the boundary between two different air masses (between the polar and eddy regimes--air nearer to the poles is generally cold and dry whereas at mid-latitudes it is warmer and also influenced by the tropics). This region is influenced by the North Atlantic Oscillation (NAO) phenomenon in which the circulation patterns vary dramatically. 

The pronounced weekly variation in the ash dispersal may result from the varying eddies that pass by the region of the volcano. The eddies are mesoscale (order of 1000 km), and thus which eddy occupies the region during the eruption would serve as the main determinant of the ashes' dispersal. Moreover, the local variance has significant downstream effects. In simulation for the eruption on January 1, 2010, the ash reached the U.S. whereas in the simulation a week later on January 8, 2010, the ash reached Russia.Although the eruptions contributing to the majority of ash fall lasted for 6 days, the simulations will cover the first three days of eruptions. 

April 14-16, 2010

First we will simulate the eruption on its actual eruption date of April 14th. 

Image Added

Image 3: 3-day ash dispersal simulation for Eyjafjallajokull for actual eruption date of April 14, 2010. The plume initially moves north-eastward and then south-westard. As the plume moves northward it deflects to the east and as it moves southward it deflects to the west as predicted by the rightward deflection of the coriolis force in the northern hemisphere. The two layers closest to the Earth's surface spread the furthest. 

...

moves poleward cyclonically. 

Concluding Remarks

Conclusions

By simulating Eyjafjallajokull for various eruption dates, I sought to investigate how the circulation patterns changed both seasonally and weekly and whether the seasonal versus weakly variations dominated the ash dispersal patterns. Simulations showed that the weekly changes in atmospheric circulation patterns dominated any seasonal trends. Eyjafjallajokull sits at the boundary between two different air masses (between the polar and eddy regimes--air nearer to the poles is generally cold and dry whereas at mid-latitudes it is warmer and also influenced by the tropics). This region is influenced by the North Atlantic Oscillation (NAO) phenomenon in which the circulation patterns vary dramatically. 

The pronounced weekly variation in the ash dispersal may result from the varying eddies that pass by the region of the volcano. The eddies are mesoscale (order of 1000 km), and thus which eddy occupies the region during the eruption would likely function as the main determinant of the ashes' dispersal. Moreover, the local variance has significant downstream effects. In simulation for the eruption on January 1, 2010, the ash reached the U.S. whereas in the simulation a week later on January 8, 2010, the ash reached RussiaIn order to understand over what time periods the ash dispersal would vary, one must look into the time scales of the eddys in the Icelandic region. Further simulations should explore variations in dispersal from daily changes to the eruption date.

Our simulations also give us insights into our record of past volcanoes. We often research past volcanoes through the ash they deposited in Greenland ice cores. Given that in many of our simulations the ash from our Icelandic volcano did not reach its neighboring country, we may likely not have lack recordings for many past local volcanoes. 

Next Steps

In order to understand the smallest time period over which changing the eruption date would cause the ash dispersal to vary, one must look into the time scales of the eddys in the Icelandic region. Further simulations should explore variations in dispersal from daily changes to the eruption date.