Abstract
Abstract. Volcanic ash transport and dispersion (VATD) models are used to forecast tephra deposition during volcanic eruptions. Model accuracy is limited by the fact that fine-ash aggregates (clumps into clusters), thus altering patterns of deposition. In most models this is accounted for by ad hoc changes to model input, representing fine ash as aggregates with density ρagg, and a log-normal size distribution with median μagg and standard deviation σagg. Optimal values may vary between eruptions. To test the variance, we used the Ash3d tephra model to simulate four deposits: 18 May 1980 Mount St. Helens; 16–17 September 1992 Crater Peak (Mount Spurr); 17 June 1996 Ruapehu; and 23 March 2009 Mount Redoubt. In 192 simulations, we systematically varied μagg and σagg, holding ρagg constant at 600 kg m−3. We evaluated the fit using three indices that compare modeled versus measured (1) mass load at sample locations; (2) mass load versus distance along the dispersal axis; and (3) isomass area. For all deposits, under these inputs, the best-fit value of μagg ranged narrowly between ∼ 2.3 and 2.7φ (0.20–0.15 mm), despite large variations in erupted mass (0.25–50 Tg), plume height (8.5–25 km), mass fraction of fine ( < 0.063 mm) ash (3–59 %), atmospheric temperature, and water content between these eruptions. This close agreement suggests that aggregation may be treated as a discrete process that is insensitive to eruptive style or magnitude. This result offers the potential for a simple, computationally efficient parameterization scheme for use in operational model forecasts. Further research may indicate whether this narrow range also reflects physical constraints on processes in the evolving cloud.
Highlights
Airborne tephra is the most wide reaching of volcanic hazards
We focus on eruptions that lasted for hours, where the total particlesize distribution (TPSD)
For model forecasts during an eruption, we need some understanding of this variability. This paper addresses this question, using deposits from four well-documented eruptions
Summary
Airborne tephra is the most wide reaching of volcanic hazards. It can extend hundreds to thousands of kilometers from a volcano and impact air quality, transportation, crops, electrical infrastructure, buildings, water supplies, and sewerage.During eruptions, communities want to know whether they may receive tephra and how much might fall. Volcano observatories typically forecast areas at risk by running volcanic ash transport and dispersion (VATD) models. As input, these models require information including eruption start time, plume height, duration, the wind field, and the size distribution of the falling particles. We focus on eruptions that lasted for hours (not days), where the TPSD included at least a few percent of ash finer than 0.063 mm in diameter, and where data were available from distal (> 35 km) sample locations Four eruptions met these criteria: the 18 May 1980 eruption of Mount St. Helens, the 16–. The August Crater Peak eruption was already studied using Ash3d (Schwaiger et al, 2012) and not included here, reducing the total to three To these we add event 5 from the 23 March 2009 eruption of Mount Redoubt, Alaska.
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