Pyroclastic dune bedforms: macroscale structures and lateral variations. Examples from the 2006 pyroclastic currents at Tungurahua (Ecuador)

Douillet, Guilhem Amin; Bernard, Benjamin; Bouysson, Mélanie; Chaffaut, Quentin; Dingwell, Donald B.; Gegg, Lukas; Hoelscher, Inga; Kueppers, Ulrich; Mato, Célia; Ritz, Vanille A.

doi:10.31223/osf.io/3sxtf

Cited by 1 publication

(1 citation statement)

References 31 publications

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“…Most PDCs, due to their high temperature, will be dominated by 2-way and 4-way coupling, as they become buoyant and transform into a co-PDC plume when concentrations drop below C<~10 −4 (e.g., Lube et al, 2020). Concentration and mass loading impacts the settling velocity of particles (Breard et al, 2016;Weit et al, 2018;Penlou et al, 2023), and in turn this impacts the density stratification and partitioning of mass between the basal granular layer (i.e., the bedload) and overriding turbulent suspension (Douillet et al, 2014(Douillet et al, , 2019Brosch and Lube, 2020). The concentration of particles in PDCs is expected to be heterogeneous temporally and spatially at any given location due to particle clustering.…”

Section: Particle Concentration and Voidagementioning

confidence: 99%

Physical properties of pyroclastic density currents: relevance, challenges and future directions

Jones,

Beckett,

Bernard

et al. 2023

Front. Earth Sci.

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Pyroclastic density currents (PDCs) are hazardous and destructive phenomena that pose a significant threat to communities living in the proximity of active volcanoes. PDCs are ground-hugging density currents comprised of high temperature mixtures of pyroclasts, lithics, and gas that can propagate kilometres away from their source. The physical properties of the solid particles, such as their grain size distribution, morphology, density, and componentry play a crucial role in determining the dynamics and impact of these flows. The modification of these properties during transport also records the causative physical processes such as deposition and particle fragmentation. Understanding these processes from the study of deposits from PDCs and related co-PDC plumes is essential for developing effective hazard assessment and risk management strategies. In this article, we describe the importance and relevance of the physical properties of PDC deposits and provide a perspective on the challenges associated with their measurement and characterization. We also discuss emerging topics and future research directions such as electrical charging, granular rheology, ultra-fine ash and thermal and surface properties that are underpinned by the characterization of pyroclasts and their interactions at the micro-scale. We highlight the need to systematically integrate experiments, field observations, and laboratory measurements into numerical modelling approaches for improving our understanding of PDCs. Additionally, we outline a need for the development of standardised protocols and methodologies for the measurement and reporting of physical properties of PDC deposits. This will ensure comparability, reproducibility of results from field studies and also ensure the data are sufficient to benchmark future numerical models of PDCs. This will support more accurate simulations that guide hazard and risk assessments.

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