2021
DOI: 10.3389/feart.2021.704797
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Simulating the Transport and Dispersal of Volcanic Ash Clouds With Initial Conditions Created by a 3D Plume Model

Abstract: Volcanic ash transport and dispersion (VATD) models simulate atmospheric transport of ash from a volcanic source represented by parameterized concentration of ash with height. Most VATD models represent the volcanic plume source as a simple line with a parameterized ash emission rate as a function of height, constrained only by a total mass eruption rate (MER) for a given total rise height. However, the actual vertical ash distribution in volcanic plumes varies from case to case, having complex dependencies on… Show more

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Cited by 6 publications
(3 citation statements)
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“…This is Laboratory of Excellence ClerVolc contribution number 538. This research was also partially financed by the French government IDEX-ISITE initiative 16-IDEX-0001 (CAP [20][21][22][23][24][25]. Acknowledgments: Nourddine Azzaoui is acknowledged for assistance in running the simulations through the cluster of Laboratoire de mathématiques Blaise Pascal, Universitè Clermont Auvergne.…”
Section: Data Availability Statementmentioning
confidence: 99%
See 1 more Smart Citation
“…This is Laboratory of Excellence ClerVolc contribution number 538. This research was also partially financed by the French government IDEX-ISITE initiative 16-IDEX-0001 (CAP [20][21][22][23][24][25]. Acknowledgments: Nourddine Azzaoui is acknowledged for assistance in running the simulations through the cluster of Laboratoire de mathématiques Blaise Pascal, Universitè Clermont Auvergne.…”
Section: Data Availability Statementmentioning
confidence: 99%
“…The same models are also widely used in the production of tephra fallout probabilistic hazard maps. Regarding the source conditions (i.e., the spatio-temporal release of particles/mass from the eruption column to the volcanic cloud), they could range from simple geometric distributions to 1D integral models [2] and 3D models [24], while complex multicomponent and multiphase flow models are still too expensive from a computational point of view [20]. Meteorological data (typically wind field, air density/temperature, and, in some cases, humidity, pressure, boundary layer altitude, turbulence, and precipitation) are necessary to simulate the transport of tephra cloud.…”
Section: Introductionmentioning
confidence: 99%
“…By absorbing terrestrial radiation and scattering the solar radiation, volcanic ashes also have a significant influence on the Earth's radiation balance (Laakso et al, 2016;Zhu et al, 2020) The properties of ash clouds such as plume height, concentration and particle size distribution are studied by ground-based and satellite remote sensing techniques. The prediction of ash cloud trajectories has required the development of transport and dispersion models of in-situ volcanic ash that can calculate the trajectory of an ash cloud at the scale of a continent or the hemisphere (Cao, Bursik, Yang, & Patra, 2021;Harvey et al, 2018;Heffter & Stunder, 1993;Peterson et al, 2015). Volcanological parameters such as plume height, eruptive rate, duration of eruption, ash distribution with altitude and particle size distribution are essential in real time during an event to constrain these models, often with limited observations (de Michele et al, 2019;Stohl et al, 2011).…”
Section: Introductionmentioning
confidence: 99%