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2. Quantifying Gas Hazard with VIGIL (Automatized Probabilistic VolcanIc Gas DIspersion Modelling)

Author

Dioguardi, Fabio, Massaro, Silvia, Chiodini, Giovanni, Costa, Antonio, Folch, Arnau, Macedonio, Giovanni, Sandri, Laura, Selva, Jacopo, Tamburello, Giancarlo, Pisello, Anna Laura, Editorial Board Member, Hawkes, Dean, Editorial Board Member, Bougdah, Hocine, Editorial Board Member, Rosso, Federica, Editorial Board Member, Abdalla, Hassan, Editorial Board Member, Boemi, Sofia-Natalia, Editorial Board Member, Mohareb, Nabil, Editorial Board Member, Mesbah Elkaffas, Saleh, Editorial Board Member, Bozonnet, Emmanuel, Editorial Board Member, Pignatta, Gloria, Editorial Board Member, Mahgoub, Yasser, Editorial Board Member, De Bonis, Luciano, Editorial Board Member, Kostopoulou, Stella, Editorial Board Member, Pradhan, Biswajeet, Editorial Board Member, Abdul Mannan, Md., Editorial Board Member, Alalouch, Chaham, Editorial Board Member, Gawad, Iman O., Editorial Board Member, Nayyar, Anand, Editorial Board Member, Amer, Mourad, Series Editor, Çiner, Attila, editor, Naitza, Stefano, editor, Radwan, Ahmed E., editor, Hamimi, Zakaria, editor, Lucci, Federico, editor, Knight, Jasper, editor, Cucciniello, Ciro, editor, Banerjee, Santanu, editor, Chennaoui, Hasnaa, editor, Doronzo, Domenico M., editor, Candeias, Carla, editor, Rodrigo-Comino, Jesús, editor, Kalatehjari, Roohollah, editor, Shah, Afroz Ahmad, editor, Gentilucci, Matteo, editor, Panagoulia, Dionysia, editor, Chaminé, Helder I., editor, Barbieri, Maurizio, editor, and Ergüler, Zeynal Abiddin, editor

Published
2024
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3. Model Validation of Passive Gas Dispersion: Examples from La Solfatara (Campi Flegrei, Italy) and Caldeiras Da Ribeira Grande (São Miguel Island, Azores)

Author

Massaro, Silvia, Stocchi, Manuel, Tamburello, Giancarlo, Dioguardi, Fabio, Costa, Antonio, Sandri, Laura, Selva, Jacopo, Macedonio, Giovanni, Folch, Arnau, Viveiros, Fátima, Chiodini, Giovanni, Caliro, Stefano, Andrade, César, Pisello, Anna Laura, Editorial Board Member, Hawkes, Dean, Editorial Board Member, Bougdah, Hocine, Editorial Board Member, Rosso, Federica, Editorial Board Member, Abdalla, Hassan, Editorial Board Member, Boemi, Sofia-Natalia, Editorial Board Member, Mohareb, Nabil, Editorial Board Member, Mesbah Elkaffas, Saleh, Editorial Board Member, Bozonnet, Emmanuel, Editorial Board Member, Pignatta, Gloria, Editorial Board Member, Mahgoub, Yasser, Editorial Board Member, De Bonis, Luciano, Editorial Board Member, Kostopoulou, Stella, Editorial Board Member, Pradhan, Biswajeet, Editorial Board Member, Abdul Mannan, Md., Editorial Board Member, Alalouch, Chaham, Editorial Board Member, Gawad, Iman O., Editorial Board Member, Nayyar, Anand, Editorial Board Member, Amer, Mourad, Series Editor, Çiner, Attila, editor, Naitza, Stefano, editor, Radwan, Ahmed E., editor, Hamimi, Zakaria, editor, Lucci, Federico, editor, Knight, Jasper, editor, Cucciniello, Ciro, editor, Banerjee, Santanu, editor, Chennaoui, Hasnaa, editor, Doronzo, Domenico M., editor, Candeias, Carla, editor, Rodrigo-Comino, Jesús, editor, Kalatehjari, Roohollah, editor, Shah, Afroz Ahmad, editor, Gentilucci, Matteo, editor, Panagoulia, Dionysia, editor, Chaminé, Helder I., editor, Barbieri, Maurizio, editor, and Ergüler, Zeynal Abiddin, editor

Published
2024
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6. Quantification of volcanic degassing and analysis of uncertainties using numerical modelling: the case of Stephanos crater (Nisyros Island, Greece)

Author

Massaro, Silvia, primary, Tamburello, Giancarlo, additional, Bini, Giulio, additional, Costa, Antonio, additional, Stocchi, Manuel, additional, Tassi, Franco, additional, Biagi, Rebecca, additional, Vaselli, Orlando, additional, Chiodini, Giovanni, additional, Dioguardi, Fabio, additional, Selva, Jacopo, additional, Sandri, Laura, additional, Macedonio, Giovanni, additional, Caliro, Stefano, additional, and Vougioukalakis, Georges, additional

Published
2024
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9. A novel view of the destruction of Pompeii during the 79 CE eruption of Vesuvius (Italy): syn-eruptive earthquakes as an additional cause of building collapse and deaths.

Author

Sparice, Domenico, Amoretti, Valeria, Galadini, Fabrizio, Di Vito, Mauro A., Terracciano, Antonella, Scarpati, Giuseppe, Zuchtriegel, Gabriel, Passaro, Salvatore, and Dioguardi, Fabio

Subjects
BUILDING failures, POMPEII, CRUSH syndrome, DYNAMIC pressure, ARCHAEOLOGICAL excavations, VOLCANIC eruptions
Abstract

The ancient city of Pompeii, destroyed by the 79 CE Plinian eruption of Vesuvius, is one of the most famous archaeological sites worldwide and an open-air laboratory for many disciplines. The destruction of Pompeii has so far been reconstructed in terms of a succession of volcanic phenomena and related effects, identified as the accumulation of pumice lapilli on roofs and dynamic pressure exerted by pyroclastic currents on buildings, and neglecting the potential effects of the syn-eruptive seismicity, the occurrence of which is beautifully described by an erudite eyewitness to the catastrophe, Pliny the Younger. During a recent excavation in the Insula dei Casti Amanti, in the central part of Pompeii, the peculiar evidence of building collapses, that overwhelmed two individuals, has been uncovered. The multidisciplinary investigation, involving archaeology, volcanology, and anthropology, gathered information on the construction technique of the masonry structures, the volcanological stratigraphy, the traumatic pattern of bone fractures of the skeletons, along with the detection of the wall displacements, that led to archaeoseismological considerations. The merging of the data has highlighted the need of an updated perspective in the assessment of the damage at Pompeii during the 79 CE eruption, by considering the syn-eruptive seismicity as a factor contributing to the destruction of the city and death of the inhabitants. By comparing the attitude and characteristics of different types of damage, and after ruling out any other possible damaging event, our conclusions point to the occurrence of syn-eruptive earthquake-induced failures of masonry structures. The structural collapses, based on our stratigraphic and volcanological data, are chronologically consistent with the beginning of the caldera-forming phase of the eruption which was accompanied by strong seismic shocks. The crush injuries of the skeletons of the two individuals are consistent with severe compression traumas and analogous to those shown by individuals involved in modern earthquakes testifying that, apart from other volcanic phenomena, the effects of syn-eruptive seismicity may be relevant. These outcomes lay the foundation for a more extensive study concerning the assessment of the contribution of the syn-eruptive seismic destruction at Pompeii and open new perspectives for volcanological, archaeoseismological and paleopathological studies. [ABSTRACT FROM AUTHOR]

Published
2024
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16. Probabilistic hazard assessment of the gas emission of Mefite d'Ansanto, Southern Italy.

Author

Dioguardi, Fabio, Chiodini, Giovanni, and Costa, Antonio

Subjects
RISK assessment, CARBON emissions, HYDROGEN sulfide, GASES
Abstract

The emission of gas species dangerous for human health and life is a widespread source of hazard in various natural contexts. These mainly include volcanic areas but also non-volcanic geological contexts. A notable example of the latter occurrence is the Mefite d'Ansanto area in the Southern Apennines in Italy. Here, large emissions of carbon dioxide (CO2) occur at rates that make this the largest non-volcanic CO2 gas emission in Italy and probably of the Earth. Given the topography of the area, in certain meteorological conditions a cold gas stream forms in the valleys surrounding the emission zone, which proved to be potentially lethal for humans and animals in the past. In this study we present a gas hazard quantification study that considers the main specie, that is CO2, and the potential effect of the most dangerous, which is hydrogen sulphide (H2S). For these purposes we used VIGIL, a tool that manages the workflow of gas dispersion simulations specifically optimised for probabilistic hazard applications. Results are discussed and presented in form of maps of CO2 and H2S concentration and persistence at various exceedance probabilities considering the gas emission rates and their possible range of variation defined in previous studies. [ABSTRACT FROM AUTHOR]

Published
2023
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18. Drag forces at the ice-sheet bed and resistance of hard-rock obstacles : the physics of glacial ripping

Author

Krabbendam, Maarten, Dioguardi, Fabio, Arnhardt, Christian, Roberson, Sam, Hall, Adrian M., Krabbendam, Maarten, Dioguardi, Fabio, Arnhardt, Christian, Roberson, Sam, and Hall, Adrian M.

Abstract

Glacial ripping involves glaciotectonic disintegration of rock hills and extensive removal of rock at the ice-sheet bed, triggered by hydraulic jacking caused by fluctuating water pressures. Evidence from eastern Sweden shows that glacial ripping caused significant subglacial erosion during the final deglaciation of the Fennoscandian ice sheet, distinct from abrasion and plucking (quarrying). Here we analyse the ice drag forces exerted onto rock obstacles at the base of an ice sheet, and the resisting forces of such rock obstacles: glaciotectonic disintegration requires that ice drag forces exceed the resisting forces of the rock obstacle. We consider rock obstacles of different sizes, shapes and fracture patterns, informed by natural examples from eastern Sweden. Our analysis shows that limited overpressure events, unfavourable fracture patterns, low-transmissivity fractures, slow ice and streamlined rock hamper rock hill disintegration. Conversely, under fast ice flow and fluctuating water pressures, disintegration is possible if the rock hill contains subhorizontal, transmissive fractures. Rock steps on previously smooth, abraded surfaces, caused by hydraulic jacking, also enhance drag forces and can cause disintegration of a rock hill. Glacial ripping is a physically plausible erosion mechanism, under realistic glaciological conditions prevalent near ice margins.

Published
2023
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19. Physical properties of pyroclastic density currents : relevance, challenges and future directions

Author

Jones, Thomas J., Beckett, Frances, Bernard, Benjamin, Breard, Eric C. P., Dioguardi, Fabio, Dufek, Josef, Engwell, Samantha, Eychenne, Julia, Jones, Thomas J., Beckett, Frances, Bernard, Benjamin, Breard, Eric C. P., Dioguardi, Fabio, Dufek, Josef, Engwell, Samantha, and Eychenne, Julia

Abstract

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.

Published
2023

20. Conducting Multi-Agency Volcanic Ash Cloud Exercises: Practicing forecast evaluation procedures and the pull-through of scientific advice to the London VAAC

Author

Beckett, Frances, Barsotti, Sara, Burton, Ralph, Dioguardi, Fabio, Engwell, Samantha, Kristiansen, Nina, Loughlin, Sue, Muscat, Anton, Osborne, Martin, Saint, Cameron, Stevenson, John, Valters, Declan, Witham, Claire, Beckett, Frances, Barsotti, Sara, Burton, Ralph, Dioguardi, Fabio, Engwell, Samantha, Kristiansen, Nina, Loughlin, Sue, Muscat, Anton, Osborne, Martin, Saint, Cameron, Stevenson, John, Valters, Declan, and Witham, Claire

Abstract

Practising and testing emergency procedures are fundamental for ensuring an effective operational response to a crisis. In this presentation we will introduce a new series of exercises which have been developed to test the multi-agency response needed to produce volcanic ash forecasts at the London Volcanic Ash Advisory Centre (VAAC). Our exercises have been specifically designed to practice our ability to interpret and evaluate model simulations and observations, the pull through of international scientific expertise into the London VAAC, and decision-making procedures under uncertainty. In this presentation we will describe our exercise methodology, this includes the development of simulated observations for exercise conditions, and a framework for comparing transport and dispersion simulations generated using different model setups (multi-model ensemble). We will also discuss how we practice the necessary interactions between scientists supporting the London VAAC and external collaborators, which may include experts at volcano observatories, national/state geological or geophysical institutions, and volcano research institutions. We will present case-studies of exercises for hypothetical events in Iceland and outline the lessons learnt. Our Exercises have not only improved our ability to respond to a volcanic ash cloud event but have also driven scientific and technical improvement of the forecasts, and strengthened the relationships between collaborators and responders, with the aim of providing the best possible advice to the London VAAC.

Published
2023

21. Improving Probabilistic Gas Hazard Assessment through HPC: Unveiling VIGIL-2.0, an automatic Python workflow for probabilistic gas dispersion modelling

Author

Massaro, Silvia, Dioguardi, Fabio, Guerrero, Alejandra, Costa, Antonio, Folch, Arnau, Sulpizio, Roberto, Macedonio, Giovanni, Mingari, Leonardo, Massaro, Silvia, Dioguardi, Fabio, Guerrero, Alejandra, Costa, Antonio, Folch, Arnau, Sulpizio, Roberto, Macedonio, Giovanni, and Mingari, Leonardo

Abstract

The atmospheric dispersion of gases (of natural or industrial origins) can be very hazardous to life and the environment if the concentration of some gas species overcome specie-specific thresholds. In this context, the natural variability associated to the natural phenomena has to be explored to provide robust probabilistic gas dispersion hazard assessments. VIGIL-1.3 (automatic probabilistic VolcanIc Gas dIspersion modeLling) is a Python simulation tool born to automatize the complex and time-consuming simulation workflow required to process a large number of gas dispersion numerical simulations. It is interfaced with two models: a dilute (DISGAS) and a dense gas (TWODEE-2) dispersion model. The former is used when the density of the gas plume at the source is lower than the atmospheric density (e.g. fumaroles), the latter when the gas density is higher than the atmosphere and the gas accumulates on the ground and may flow due to the density contrast with the atmosphere to form a gravity current (e.g. cold CO2 flows). In the enhancement of the code towards a higher-scale computing, here we present the ongoing improvements aimed to extend some code functionalities such as memory management, modularity revision, and full-ensemble uncertainty on gas dispersal scenarios (e.g. sampling techniques for gas fluxes and source locations). Optimizations are also provided in terms of tracking errors, redesignation of the input file, validation of data provided by the users, and addition of the Latin hypercube sampling (LHS) for the post-processing of model outputs. All these new features will be issued in the future release of the code (VIGIL-2.0) in order to facilitate the users which could run VIGIL on laptops or large supercomputer, and to widen the spectrum of model applications from routinely operational forecast of volcanic gas to long-term hazard and/or risk assessments purposes.

Published
2023

24. Probabilistic hazard maps of dilute pyroclastic density current at Vesuvius

Author

Dellino, Pierfrancesco, Mele, Daniela, Sulpizio, Roberto, and Dioguardi, Fabio

Abstract

Dilute pyroclastic density currents are one major source of hazard at Vesuvius. By combining data of deposits of the explosive eruptions of the last six thousand years and interpolating data of impact parameters (Velocity, Density, particle volumetric concentration, temperature, dynamic pressure), which were calculated by modeling the currents as stratified turbulent boundary layer flows, probabilistic hazard maps were obtained. They show the decay trend of the impact as a function of distance from the vent and allow depicting the expected damage. This outcome can help civil protection authorities to more precisely-implemented mitigation measures and communicate more effectively the risk to decision-makers and the population., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published
2023

25. Quantifying uncertainties in numerical simulations and gas hazard assessment of volcanic gas dispersion

Author

Massaro, Silvia, Costa, Antonio, Stocchi, Manuel, Dioguardi, Fabio, Tamburello, Giancarlo, Sandri, Laura, Selva, Jacopo, Folch, Arnau, Macedonio, Giovanni, Viveiros, Fatima, and Vougioukalakis, Georges

Abstract

The emission of volcanic gases can occur during both eruptive and quiescent stages of volcanic activity, affecting air quality when the concentrations exceed species-specific thresholds. Quantitative studies of model validation are essential before applying a simulator for probabilistic volcanic hazard assessment. Here, we provide three examples of model validation aimed at testing the accuracy in providing realistic values of CO2 concentration, estimating the source gas fluxes using the concentration measurements through resolution of the inverse problem, and identifying potential hazardous gas dispersal scenarios. We selected three case study affected by a persistent diffusive and fumarolic degassing: i) La Solfatara crater, Campi Flegrei caldera, Italy, ii) Caldeiras da Ribeira Grande, São Miguel Island, Azores and iii) Stefanos crater, Nisyros Island, Greece. We used published and original CO2 flux data as input for numerical simulations run through VIGIL, an open-source workflow for parallel simulations and probabilistic output using two Eulerian models, which account for the passive and gravity-driven gas transport, respectively. Our results provided probabilistic CO2 concentration maps at 0.5-1.5 m from the ground in order to investigate the potential effects on human and animal health, and statistical tests aimed to infer the best scaling factor for gas flux in reaching hazardous gas concentrations. This kind of methodology has revelad the potential usefulness of the modeling in reproducing the order of magnitude of the observed degassing, therefore, such a testing should be the first logical step to be taken before applying a simulator to assess (gas) hazard in any other volcanic contexts., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published
2023

26. Towards a long-term multi-hazard assessment from Neapolitan volcanoes (Southern Italy)

Author

Massaro, Silvia, Stocchi, Manuel, Martinez Montesinos, Beatriz, Sandri, Laura, Selva, Jacopo, Costa, Antonio, Dellino, Pierfrancesco, Dioguardi, Fabio, Mele, Daniela, and Sulpizio, Roberto

Abstract

The Neapolitan volcanoes are some of the most hazardous in the world because capable of large explosive eruptions releasing threatening quantities of ash in the atmosphere that would reasonably reach highly-populated urban areas, even at considerable distances from the sources. This study aims to show a long-term tephra fallout hazard evaluation posed by the Neapolitan volcanoes (Somma-Vesuvius, Campi Flegrei, Ischia) in Southern Italy, and to track future perspectives to combine a multi-hazard assessment to a more local-scale domain. Through a new HPC workflow for volcanic hazard assessment based on a Bayesian procedure, we provided the mean annual frequency with which the tephra load at the ground exceeds given critical thresholds within 50 years. By performing hazard disaggregation, we also got specific information about the prevalence of different volcanoes and eruptive style in the different target areas. Thousands of numerical simulations were run with the FALL3D model to create a large synthetic dataset of tephra ground loads on a 0.03°-resolution gridded domain and a vertical σ-coordinate system with a linear decay. Each simulation took a randomly sampled set of eruptive source parameters within the ranges established by the knowledge of each volcano and meteorological conditions extracted by the ECMWF ERA5 dataset. In particular, results show that the greater tephra load thresholds are exceeded with longer averaged return times (i.e., 100, 500, 1000 years) in the proximity of the Neapolitan area. This pushes us to do a step forward into a more detailed multi-hazard and risk-ranking quantification in the Neapolitan urban area., The 28th IUGG General Assembly (IUGG2023) (Berlin 2023)

Published
2023

30. VIGIL: a Python tool for automatized probabilistic VolcanIc Gas dIspersion modeLling

Author

Dioguardi, Fabio, Massaro, Silvia, Chiodini, Giovanni, Costa, Antonio, Folch, Arnau, Macedonio, Giovanni, Sandri, Laura, Selva, Jacopo, Tamburello, Giancarlo, Dioguardi, Fabio, Massaro, Silvia, Chiodini, Giovanni, Costa, Antonio, Folch, Arnau, Macedonio, Giovanni, Sandri, Laura, Selva, Jacopo, and Tamburello, Giancarlo

Abstract

Probabilistic volcanic hazard assessment is a standard methodology based on running a deterministic hazard quantification tool multiple times to explore the full range of uncertainty in the input parameters and boundary conditions, in order to probabilistically quantify the variability of outputs accounting for such uncertainties. Nowadays, different volcanic hazards are quantified by means of this approach. Among these, volcanic gas emission is particularly relevant given the threat posed to human health if concentrations and exposure times exceed certain thresholds. There are different types of gas emissions but two main scenarios can be recognized: hot buoyant gas emissions from fumaroles and the ground and dense gas emissions feeding density currents that can occur, e.g., in limnic eruptions. Simulation tools are available to model the evolution of critical gas concentrations over an area of interest. Moreover, in order to perform probabilistic hazard assessments of volcanic gases, simulations should account for the natural variability associated to aspects such as seasonal and daily wind conditions, localized or diffuse source locations, and gas fluxes. Here we present VIGIL (automatized probabilistic VolcanIc Gas dIspersion modeLling), a new Python tool designed for managing the entire simulation workflow involved in single and probabilistic applications of gas dispersion modelling. VIGIL is able to manage the whole process from meteorological data processing, needed to run gas dispersion in both the dilute and dense gas flow scenarios, to the post processing of models’ outputs. Two application examples are presented to show some of the modelling capabilities offered by VIGIL.

Published
2022

31. Drag forces at the ice-sheet bed and resistance of hard-rock obstacles: the physics of glacial ripping

Author

Krabbendam, Maarten, Dioguardi, Fabio, Arnhardt, Christian, Roberson, Sam, Hall, Adrian M., Krabbendam, Maarten, Dioguardi, Fabio, Arnhardt, Christian, Roberson, Sam, and Hall, Adrian M.

Abstract

Glacial ripping involves glaciotectonic disintegration of rock hills and extensive removal of rock at the ice-sheet bed, triggered by hydraulic jacking caused by fluctuating water pressures. Evidence from eastern Sweden shows that glacial ripping caused significant subglacial erosion during the final deglaciation of the Fennoscandian ice sheet, distinct from abrasion and plucking (quarrying). Here we analyse the ice drag forces exerted onto rock obstacles at the base of an ice sheet, and the resisting forces of such rock obstacles: glaciotectonic disintegration requires that ice drag forces exceed the resisting forces of the rock obstacle. We consider rock obstacles of different sizes, shapes and fracture patterns, informed by natural examples from eastern Sweden. Our analysis shows that limited overpressure events, unfavourable fracture patterns, low-transmissivity fractures, slow ice and streamlined rock hamper rock hill disintegration. Conversely, under fast ice flow and fluctuating water pressures, disintegration is possible if the rock hill contains subhorizontal, transmissive fractures. Rock steps on previously smooth, abraded surfaces, caused by hydraulic jacking, also enhance drag forces and can cause disintegration of a rock hill. Glacial ripping is a physically plausible erosion mechanism, under realistic glaciological conditions prevalent near ice margins.

Published
2022

32. VIGIL: A Python tool for automatized probabilistic VolcanIc Gas dIspersion modeLling

Author

National capability funding (UK), European Commission, Folch, Arnau [0000-0002-0677-6366], Dioguardi, Fabio, Massaro, Silvia, Chiodini, Giovanni, Costa, Antonio, Folch, Arnau, Macedonio, Giovanni, Sandri, Laura, Selva, Jacopo, Tamburello, Giancarlo, National capability funding (UK), European Commission, Folch, Arnau [0000-0002-0677-6366], Dioguardi, Fabio, Massaro, Silvia, Chiodini, Giovanni, Costa, Antonio, Folch, Arnau, Macedonio, Giovanni, Sandri, Laura, Selva, Jacopo, and Tamburello, Giancarlo

Abstract

Probabilistic volcanic hazard assessment is a standard methodology based on running a deterministic hazard quantification tool multiple times to explore the full range of uncertainty in the input parameters and boundary conditions, in order to probabilistically quantify the variability of outputs accounting for such uncertainties. Nowadays, different volcanic hazards are quantified by means of this approach. Among these, volcanic gas emission is particularly relevant given the threat posed to human health if concentrations and exposure times exceed certain thresholds. There are different types of gas emissions but two main scenarios can be recognized: hot buoyant gas emissions from fumaroles and the ground and dense gas emissions feeding density currents that can occur, e.g., in limnic eruptions. Simulation tools are available to model the evolution of critical gas concentrations over an area of interest. Moreover, in order to perform probabilistic hazard assessments of volcanic gases, simulations should account for the natural variability associated to aspects such as seasonal and daily wind conditions, localized or diffuse source locations, and gas fluxes. Here we present VIGIL (automatized probabilistic VolcanIc Gas dIspersion modeLling), a new Python tool designed for managing the entire simulation workflow involved in single and probabilistic applications of gas dispersion modelling. VIGIL is able to manage the whole process from meteorological data processing, needed to run gas dispersion in both the dilute and dense gas flow scenarios, to the post processing of models' outputs. Two application examples are presented to show some of the modelling capabilities offered by VIGIL.

Published
2022

40. The Impact of Eruption Source Parameter Uncertainties on Ash Dispersion Forecasts During Explosive Volcanic Eruptions

Author

Dioguardi, Fabio, Beckett, Frances, Dürig, Tobias, Stevenson, John A., Jarðvísindastofnun (HÍ), Institute of Earth Sciences (UI), Verkfræði- og náttúruvísindasvið (HÍ), School of Engineering and Natural Sciences (UI), Háskóli Íslands, and University of Iceland

Subjects
Aska, Atmospheric Science, 010504 meteorology & atmospheric sciences, Explosive material, Mineralogy, Eruption source parameters, 010502 geochemistry & geophysics, 01 natural sciences, Explosive volcanic eruptions, Dispersion (optics), Earth and Planetary Sciences (miscellaneous), Sprengigos, 0105 earth and related environmental sciences, geography, geography.geographical_feature_category, Buoyant plume models, Dispersion modeling, Atmospheric dispersion modeling, Geophysics, Volcano, 13. Climate action, Space and Planetary Science, Environmental science, Spálíkön, Volcanic ash
Abstract

Publisher's version (útgefin grein), Volcanic ash in the atmosphere is a hazard to aviation. To predict which areas of airspace are most likely to be affected by the presence of ash, Volcanic Ash Advisory Centers (VAACs) use observations and atmospheric dispersion models. These models are initialized with, among other parameters, a mass eruption rate (MER), which quantifies the emission rate into the atmosphere at the source. This influences the predicted spatial–temporal evolution and concentration of the ash cloud. Different models are available to estimate MER from the volcanic plume height and some models also include the weather conditions (e.g., wind speed). The REFIR software tool uses time-series of plume height estimated from observations and weather data to provide estimates of MER through time. Here we present an updated version of REFIR that can now be used also to calculate MER for past eruptions and produce output parameters in a format suitable for use with the NAME dispersion model (UK Met Office—London VAAC). We also investigate how uncertainty in input parameters is propagated through to dispersion model output. Our results show that a +/−1 km uncertainty on a 6 km high plume can result in the affected area ranging by a factor of three between the minimum and maximum estimates. Additionally, we show that using wind-affected plume models results in affected areas that are five times larger than using no-wind-affected models. This demonstrates the sensitivity of MER to the type of plume model chosen (no-wind- vs. wind-affected)., We thank Larry Mastin, Arnau Folch, and an anonymous reviewer for their comments and suggestions that contributed to the improvement of the manuscript, and Lynn Russell for the editorial handling. We also thank Dr. Susan Loughlin (British Geological Survey), Dr. Susan Leadbetter (UK Met Office) and Dr. Claire Witham (UK Met Office) for their valuable suggestions. Fabio Dioguardi and John A. Stevenson have been supported from UK National Capability funding (BGS Innovation Flexible Fund). Fabio Dioguardi has also been supported by the European Union's Horizon 2020 project EUROVOLC (grant agreement no 731070). Tobias D?rig's work is supported by the Icelandic Research Fund (Rann?s) grant no. 206527-051. This work is published with permission of the Executive Director of British Geological Survey (UKRI)

Published
2020

42. Multi-hazard quantifications of the volcanic phenomena at La Soufrière volcano (Guadeloupe, Lesser Antilles)

Author

Massaro, Silvia, primary, Sandri, Laura, additional, Selva, Jacopo, additional, Dioguardi, Fabio, additional, Bonadonna, Costanza, additional, Rossi, Eduardo, additional, Tamburello, Giancarlo, additional, Moretti, Roberto, additional, Komorowski, Jean-Christophe, additional, Moune, Severine, additional, Jessop, David, additional, and Costa, Antonio, additional

Published
2020
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45. The rate of sedimentation from turbulent suspension: an experimental model with application to pyroclastic density currents and discussion on the grain-size dependence of flow runout

Author

Dellino, Pierfrancesco, Dioguardi, Fabio, Doronzo, Domenico M., Mele, Daniela, Dellino, Pierfrancesco, Dioguardi, Fabio, Doronzo, Domenico M., and Mele, Daniela

Abstract

Large‐scale experiments generating ground‐hugging multiphase flows were carried out with the aim of modelling the rate of sedimentation, of pyroclastic density currents. The current was initiated by the impact on the ground of a dense gas‐particle fountain issuing from a vertical conduit. On impact, a thick massive deposit was formed. The grain size of the massive deposit was almost identical to that of the mixture feeding the fountain, suggesting that similar layers formed at the impact of a natural volcanic fountain should be representative of the parent grain‐size distribution of the eruption. The flow evolved laterally into a turbulent suspension current that sedimented a thin, tractive layer. A good correlation was found between the ratio of transported/sedimented load and the normalized Rouse number of the turbulent current. A model of the sedimentation rate was developed, which shows a relationship between grain size and flow runout. A current fed with coarser particles has a higher sedimentation rate, a larger grain‐size selectivity and runs shorter than a current fed with finer particles. Application of the model to pyroclastic deposits of Vesuvius and Campi Flegrei of Southern Italy resulted in sedimentation rates falling inside the range of experiments and allowed definition of the duration of pyroclastic density currents which add important information on the hazard of such dangerous flows. The model could possibly be extended, in the future, to other geological density currents as, for example, turbidity currents.

Published
2019

49. A study on the influence of internal structures on the shape of pyroclastic particles by X-ray microtomography investigations

Author

Mele, Daniela, Dioguardi, Fabio, Dellino, Pierfrancesco, Mele, Daniela, Dioguardi, Fabio, and Dellino, Pierfrancesco

Abstract

1.X-Ray computed microtomography is a non-destructive 3D imaging technique that can be used for the investigation of both the morphology and internal structures of a solid object. Thanks to its versatility, it is currently of common use in many research fields and applications, from medical science to geosciences. The latter include volcanology, where this analytical technique is becoming increasingly popular, in particular for quantifying the shape as well as the internal structure of particles constituting tephra deposits. Particle morphology plays a major role in controlling the mobility of pyroclastic material in the atmosphere and particle-laden flows, while the internal structure (e.g. vesicles and crystal content) is of importance for constraining the processes occurring in magmatic chamber or volcanic conduits. In this paper, we present results of X-Ray microtomography morphological and textural analyses on volcanic particles carried out to study how particle shape is influenced by their internal structures. Particles were selected from tephra generated during explosive eruptions of different magnitude and composition. Results show how particle morphology is strongly influenced by their internal structure, which is characterized by textural features like vesicularity, vesicle and solid structure distribution, vesicles inter-connection and distance between adjacent vesicles. These have been found to vary with magma composition, vesiculation and crystallization history. Furthermore, our results confirm that X-Ray microtomography is a powerful tool for investigating shape and internal structure of particles. It both allows us to characterize the particle shape by means of tridimensional shape parameters and to relate them to their internal structures.

Published
2018

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