A model for wet aggregation of ash particles in volcanic plumes and clouds: 1. Theoretical formulation

Costa, Antonio; Folch, Arnau; Macedonio, Giovanni

doi:10.1029/2009jb007175

Cited by 110 publications

(188 citation statements)

References 73 publications

(128 reference statements)

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“…in the vertical column, as aggregation due to the presence of ice seems is less effective. Costa et al (2010) also demonstrated how wet aggregation strongly depends on the ratio between the residence time of aggregating particles within the cloud region where liquid water exists and the time required for aggregates to form. As a result, aggregation processes are likely to be more effective in moderate explosions and small plumes than in vigorous Plinian and sub-Plinian eruptions characterized by fast ascending plumes.…”

Section: Empirical and Numerical Studies On Aggregationmentioning

confidence: 99%

“…Such a model was then implemented by Folch et al (2010) with good agreement. The models proposed by Costa et al (2010) and Folch et al (2010) demonstrate that wet aggregation is limited to the cloud region characterized by temperatures above the freezing point of water, i.e. in the vertical column, as aggregation due to the presence of ice seems is less effective.…”

Section: Empirical and Numerical Studies On Aggregationmentioning

confidence: 99%

“…The availability and abundance of water in the eruption cloud exerts a dominant control on aggregation (Gilbert and Lane, 1994;Veitch and Woods, 2001;Costa et al, 2010;Folch et al, 2010;Textor et al, 2006a and b). Initial fragmentation, particle collisions, mixed phase clouds and particle separation all lead to particle charging (Mather and Harrison, 2006) which influences particle collisions and may provide binding forces in the absence of water (more relevant for clouds 1000s km from source or >24 hours in age).…”

Section: Aggregation Within Ash Plumes: Conditions and Downwind Changesmentioning

confidence: 99%

“…Costa et al (2010) developed a model of wet aggregation based on the classical theory of Smoluchowski (1916) using a fractal relationship to describe the rate at which particles form aggregates based on three different collision mechanisms (i.e., Brownian motion, ambient fluid shear, and differential sedimentation). Both the effects of magmatic water and atmospheric water are considered as well as the effects of water in a liquid or solid state on aggregation.…”

Section: Empirical and Numerical Studies On Aggregationmentioning

confidence: 99%

“…Most volcanic ash finer than 125 µm settles out of the atmosphere as particle aggregates that have higher settling velocities than individual constituent particles (Carey and Sigurdsson, 1982;Sorem, 1982;Lane et al, 1993). While aggregation exerts a first order control on the dispersal of fine ash within eruption clouds, the physical and chemical processes involved are not completely understood despite significant progress over the past twenty years (Schumacher and Schmincke, 1995;Gilbert and Lane, 1994;James et al, 2002James et al, , 2003Textor et al, 2006a and b;Costa et al, 2010). Fine airborne particles adhere to each other as a result of electrostatic attraction, moist adhesion between particles (e.g., Sorem, 1982;Gilbert and Lane, 1994;Schumacher andSchmincke, 1991, 1995;James et al, 2002) and hydrometeor formation (e.g., Veitch and Woods, 2001;Textor et al, 2006a;.…”

Section: Introductionmentioning

confidence: 99%

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A review of volcanic ash aggregation

Brown

Bonadonna

Durant

2012

Physics and Chemistry of the Earth, Parts A/B/C

220

289

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. (2012) 'A review of volcanic ash aggregation.', Physics and chemistry of the earth, parts A/B/C., 45-46 . pp. 65-78. Further information on publisher's website:http://dx.doi.org/10.1016/j.pce. 2011.11.001 Publisher's copyright statement:Additional information: Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-pro t purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. AbstractMost volcanic ash particles with diameters < 63 µm settle from eruption clouds as particle aggregates that cumulatively have larger sizes, lower densities, and higher terminal fall velocities than individual constituent particles. Particle aggregation reduces the atmospheric residence time of fine ash, which results in a proportional increase in fine ash fallout within 10s km to 100s km from the volcano and a reduction in airborne fine ash mass concentrations 1000s km from the volcano. Aggregate characteristics vary with distance from the volcano: proximal aggregates are typically larger (up to cm size) with concentric structures, while distal aggregates are typically smaller (sub-millimetre size). Particles comprising ash aggregates are bound through hydro-bonds (liquid and ice water) and electrostatic forces, and the rate of particle aggregation correlates with cloud liquid water availability. Eruption source parameters (including initial particle size distribution, erupted mass, eruption column height, cloud water content and temperature) and the eruption plume temperature lapse rate, coupled with the environmental parameters, determines the type and spatiotemporal distribution of aggregates. Field studies, lab experiments and modelling investigations have already provided important insights on the process of particle aggregation. However, new integrated observations that combine remote sensing studies of 2 ash clouds with field measurement and sampling, and lab experiments are required to fill current gaps in knowledge surrounding the theory of ash aggregate formation. Abstract word count: 222

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Section: Empirical and Numerical Studies On Aggregationmentioning

confidence: 99%

Section: Empirical and Numerical Studies On Aggregationmentioning

confidence: 99%

Section: Aggregation Within Ash Plumes: Conditions and Downwind Changesmentioning

confidence: 99%

Section: Empirical and Numerical Studies On Aggregationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A review of volcanic ash aggregation

Brown

Bonadonna

Durant

2012

Physics and Chemistry of the Earth, Parts A/B/C

220

289

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Experimental investigation of the aggregation‐disaggregation of colliding volcanic ash particles in turbulent, low‐humidity suspensions

Bello

Taddeucci

Scarlato

et al. 2015

Geophysical Research Letters

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We present the results of laboratory experiments on the aggregation and disaggregation of colliding volcanic ash particles. Ash particles of different composition and size <90 μm were held in turbulent suspension and filmed in high speed while colliding, aggregating, and disaggregating, forming a growing layer of electrostatically bound particles along a vertical plate. At room conditions and regardless of composition, 60-80% of the colliding particles smaller than 32 μm remained aggregated. In contrast, aggregation of particles larger than 63 μm was negligible, and, when a layer formed, periods when disaggregation (mainly by collisions or drag) exceeded aggregation occurred twice as frequently than for smaller particles. An empirical relationship linking the aggregation index, i.e., the effective fraction of aggregated particles surviving disaggregation, to the mean particle collision kinetic energy is provided. Our results have potential implications on the dynamics of volcanic plumes and ash mobility in the environment.

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Volcanic ash layer depth: Processes and mechanisms

Dacre

Grant

Harvey

et al. 2015

Geophysical Research Letters

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The long duration of the 2010 Eyjafjallajökull eruption provided a unique opportunity to measure a widely dispersed volcanic ash cloud. Layers of volcanic ash were observed by the European Aerosol Research Lidar Network with a mean depth of 1.2 km and standard deviation of 0.9 km. In this paper we evaluate the ability of the Met Office's Numerical Atmospheric‐dispersion Modelling Environment (NAME) to simulate the observed ash layers and examine the processes controlling their depth. NAME simulates distal ash layer depths exceptionally well with a mean depth of 1.2 km and standard deviation of 0.7 km. The dominant process determining the depth of ash layers over Europe is the balance between the vertical wind shear (which acts to reduce the depth of the ash layers) and vertical turbulent mixing (which acts to deepen the layers). Interestingly, differential sedimentation of ash particles and the volcano vertical emission profile play relatively minor roles.

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A model for wet aggregation of ash particles in volcanic plumes and clouds: 1. Theoretical formulation

Cited by 110 publications

References 73 publications

A review of volcanic ash aggregation

A review of volcanic ash aggregation

Experimental investigation of the aggregation‐disaggregation of colliding volcanic ash particles in turbulent, low‐humidity suspensions

Volcanic ash layer depth: Processes and mechanisms

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