Your search keyword '"Kenneson G. Dean"' showing total 2 results

1. Dispersion modeling of volcanic ash clouds: North Pacific eruptions, the past 40 years: 1970–2010

Author

Rorik Peterson, A. Steffke, M. Harrild, J. Groves, Peter Webley, and Kenneson G. Dean

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Atmospheric dispersion modeling, Volcano, Impact crater, Observatory, Climatology, Natural hazard, Satellite remote sensing, Earth and Planetary Sciences (miscellaneous), Sea level, Geology, Water Science and Technology, Volcanic ash

Abstract

Over the last 40 years, there have been numerous volcanic eruptions across the North Pacific (NOPAC) region that posed a potential threat to both local communities and transcontinental aircraft. The ability to detect these volcanic clouds using satellite remote sensing and predict their movement by dispersion modeling is a major component of hazard mitigation. The Puff volcanic ash transport and dispersion model, used by the Alaska Volcano Observatory, was used to illustrate the impact that these volcanic ash clouds have made across the NOPAC and entire Polar region over the past 40 years. Nearly, 400 separate ash clouds were analyzed that were either reported or detected to have reached above 6 km (20,000 ft) above sea level, an average of one ash cloud every 1.25 months. Particular events showed that ash clouds can be tracked from Alaska to Greenland (Crater Peak, Mount Spurr in 1992), from Kamchatka to Alaska (Kluvicheskoi Volcano in 1994), from Alaska to California (Mount Cleveland Volcano in 2001) and from multiple events within 1 day (Mount Augustine Volcano in 2006). This study showed the vast number of events that have impacted this Polar region and how tracking them is useful for hazard mitigation.

Published

2011

2. Automated forecasting of volcanic ash dispersion utilizing Virtual Globes

Author

J. E. Bailey, Peter Webley, Jon Dehn, Rorik Peterson, and Kenneson G. Dean

Subjects

Atmospheric Science, geography, geography.geographical_feature_category, Meteorology, Numerical weather prediction, law.invention, Altitude, Volcano, Observatory, law, Natural hazard, Earth and Planetary Sciences (miscellaneous), Radiosonde, Sea level, Geology, Water Science and Technology, Volcanic ash

Abstract

There are over 100 active volcanoes in the North Pacific (NOPAC) region, most of which are located in sparsely populated areas. Dispersion models play an important role in forecasting the movement of volcanic ash clouds by complementing both remote sensing data and visual observations from the ground and aircraft. Puff is a three-dimensional dispersion model, primarily designed for forecasting volcanic ash dispersion, used by the Alaska Volcano Observatory and other agencies. Since early 2007, the model is in an automated mode to predict the movement of airborne volcanic ash at multiple elevated alert status volcanoes worldwide to provide immediate information when an eruption occurs. Twelve of the predictions are within the NOPAC region, nine more within the southern section of the Pacific ring of fire and the others are in Europe and the Caribbean. Model forecasts are made for initial ash plumes ranging from 4 to 20 km altitude above sea level and for a 24-h forecast period. This information is made available via the Puff model website. Model results can be displayed in Virtual Globes for three-dimensional visualization. Here, we show operational Puff predictions in two and three-dimensions in Google Earth®, both as iso-surfaces and particles, and study past eruptions to illustrate the capabilities that the Virtual Globes can provide. In addition, we show the opportunity that Google Maps® provides in displaying Puff operational predictions via an application programming web interface and how radiosonde data (vertical soundings) and numerical weather prediction vertical profiles can be displayed in Virtual Globes for assisting in estimating ash cloud heights.

Published

2008