Dynamics and tephra dispersal of Violent Strombolian eruptions at Vesuvius: insights from field data, wind reconstruction and numerical simulation of the 1906 event

Barsotti, Sara; Neri, Augusto; Bertagnini, A.; Cioni, Raffaello; Mulas, Maurizio; Mundula, Filippo

doi:10.1007/s00445-015-0939-6

Cited by 18 publications

(11 citation statements)

References 43 publications

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“…Barberi et al 1990;Barsotti et al 2015;Bonadonna et al 2002;Bonasia et al 2011;Capra et al 2008;Costa et al 2009;Hill et al 1998;Jenkins et al 2015;Macedonio et al 2008;Scaini et al 2012;Scollo et al 2008;Sieron et al 2014). However, the eruption source parameters of the considered reference scenario are commonly kept fixed an their variability and uncertainty are rarely taken into account.…”

Section: Introductionmentioning

confidence: 98%

Effects of eruption source parameter variation and meteorological dataset on tephra fallout hazard assessment: example from Vesuvius (Italy)

et al. 2016

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In this study, using the tephra dispersal model HAZMAP, we investigate the effect of using different meteorological datasets and eruption source parameters on tephra fallout hazard assessment for a sub-Plinian eruption of Vesuvius, which is considered as a reference case for hazard assessment analysis. We analyze the effect of using different meteorological data, from: i) radio-sounding carried out at the meteorological station of Brindisi (Italy) between 1962 and 1976 and between 1996 and 2012, and at Pratica di Mare (Rome, Italy) between 1995 and 2013; ii) meteorological models of the National Oceanic and Atmospheric Administration (NOAA), and of the European Centre for Medium-Range Weather Forecasts (ECMWF). Furthermore, we consider the effects of perturbing reference eruptive source parameters. In particular, we vary the total mass, the total grain-size distribution, the column height, and the effective atmospheric diffusion coefficient to evaluate how these parameters affect the hazard probability maps. Moreover, the effect of the seasonal variation of the wind field and the effect of the rain on the deposit loading are considered. Results show that the parameter that mostly affects hazard maps is, as expected, the total erupted mass; furthermore, keeping constant the erupted mass, the most important control on hazard is due to the particle terminal settling velocity distribution which is a function of the total grain-size distribution, particle density and shape. Within the considered range variations, the hazard depends less on the use of different meteorological datasets, column height and effective diffusion coefficient.

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Section: Introductionmentioning

confidence: 98%

Effects of eruption source parameter variation and meteorological dataset on tephra fallout hazard assessment: example from Vesuvius (Italy)

et al. 2016

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“…Continuous ash emission (AE) eruptions (e.g., AP3, AP4, and AP5, several events of Middle Age activity, 1794, and 1660)-with magnitudes up to 10 −2 km 3 and intensities <10 5 kg/s-resulted in the deposition of sequences (from few centimeters up to several decimeters thick) of ash deposits interlayered with minor lapilli beds. The most important feature of this latter type of activity is its prolonged duration (from weeks to months) (details in Cioni et al [2008] and Barsotti et al [2015]). Cioni et al [2008] discussed in detail the temporal evolution of volcanic activity at SV, by estimating the main physical parameters related to a large set of past eruptions (see Figure 3 from this paper and Table 1 from Cioni et al [2008]).…”

Section: Eruptive Historymentioning

confidence: 99%

“…Continuous ash emission (AE) eruptions (e.g., AP3, AP4, and AP5, several events of Middle Age activity, 1794, and 1660)—with magnitudes up to 10 −2 km 3 and intensities <10 5 kg/s—resulted in the deposition of sequences (from few centimeters up to several decimeters thick) of ash deposits interlayered with minor lapilli beds. The most important feature of this latter type of activity is its prolonged duration (from weeks to months) (details in Cioni et al [] and Barsotti et al []).…”

Section: Geological Setting Of Somma‐vesuviomentioning

confidence: 99%

“…The small‐scale explosive eruption data set (Figure ) comprises the violent Strombolian (VS) and continuous ash emission (AE) categories, which have been placed here into one data set to reflect similar magnitudes and intensities, although deposits and related hazards are quite different [ Cioni et al , ; Neri et al , ; Barsotti et al , ].…”

Section: The Data Setsmentioning

confidence: 99%

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Assessing future vent opening locations at the Somma‐Vesuvio volcanic complex: 1. A new information geodatabase with uncertainty characterizations

et al. 2017

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This study presents new and revised data sets about the spatial distribution of past volcanic vents, eruptive fissures, and regional/local structures of the Somma‐Vesuvio volcanic system (Italy). The innovative features of the study are the identification and quantification of important sources of uncertainty affecting interpretations of the data sets. In this regard, the spatial uncertainty of each feature is modeled by an uncertainty area, i.e., a geometric element typically represented by a polygon drawn around points or lines. The new data sets have been assembled as an updatable geodatabase that integrates and complements existing databases for Somma‐Vesuvio. The data are organized into 4 data sets and stored as 11 feature classes (points and lines for feature locations and polygons for the associated uncertainty areas), totaling more than 1700 elements. More specifically, volcanic vent and eruptive fissure elements are subdivided into feature classes according to their associated eruptive styles: (i) Plinian and sub‐Plinian eruptions (i.e., large‐ or medium‐scale explosive activity); (ii) violent Strombolian and continuous ash emission eruptions (i.e., small‐scale explosive activity); and (iii) effusive eruptions (including eruptions from both parasitic vents and eruptive fissures). Regional and local structures (i.e., deep faults) are represented as linear feature classes. To support interpretation of the eruption data, additional data sets are provided for Somma‐Vesuvio geological units and caldera morphological features. In the companion paper, the data presented here, and the associated uncertainties, are used to develop a first vent opening probability map for the Somma‐Vesuvio caldera, with specific attention focused on large or medium explosive events.

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“…Tracking puff movements within the 3D domain, the code computes at each time step the amount of mass advected out of the domain, still suspended in the atmosphere and deposited on the ground. VOL-CALPUFF has been tested and adopted to simulate volcanic ash dispersal and deposition at several volcanoes worldwide Barsotti et al 2011;Spinetti et al 2013;Barsotti et al 2015).…”

Section: Numerical Modelmentioning

confidence: 99%

Reconstructing eruptive source parameters from tephra deposit: a numerical study of medium-sized explosive eruptions at Etna volcano

2016

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Since the 1970s, multiple reconstruction techniques have been proposed and are currently used, to extrapolate and quantify eruptive parameters from sampled tephra fall deposit datasets. Atmospheric transport and deposition processes strongly control the spatial distribution of tephra deposit; therefore, a large uncertainty affects mass derived estimations especially for fall layer that are not well exposed. This paper has two main aims: the first is to analyse the sensitivity to the deposit sampling strategy of reconstruction techniques. The second is to assess whether there are differences between the modelled values for emitted mass and grainsize, versus values estimated from the deposits. We find significant differences and propose a new correction strategy. A numerical approach is demonstrated by simulating with a dispersal code a mild explosive event occurring at Mt. Now at Icelandic Meteorological Office, Reykjavík, Iceland using available tephra information collected after the eruption. A full synthetic deposit is created by integrating the deposited mass computed by the model over the computational domain (i.e., an area of 7.5 × 10 4 km 2 ). A statistical analysis based on 2000 sampling tests of 50 sampling points shows a large variability, up to 50 % for all the reconstruction techniques. Moreover, for some test examples Power Law errors are larger than estimated uncertainty. A similar analysis, on simulated grain-size classes, shows how spatial sampling limitations strongly reduce the utility of available information on the total grain size distribution. For example, information on particles coarser than φ(−4) is completely lost when sampling at 1.5 km from the vent for all columns with heights less than 2000 m above the vent. To correct for this effect an optimal sampling strategy and a new reconstruction method are presented. A sensitivity study shows that our method can be extended to a wide range of eruptive scenarios including those in which aggregation processes are important. The new correction method allows an estimate of the deficiency for each simulated class in calculated mass deposited, providing reliable estimation of uncertainties in the reconstructed total (whole deposit) grainsize distribution.

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Dynamics and tephra dispersal of Violent Strombolian eruptions at Vesuvius: insights from field data, wind reconstruction and numerical simulation of the 1906 event

Cited by 18 publications

References 43 publications

Effects of eruption source parameter variation and meteorological dataset on tephra fallout hazard assessment: example from Vesuvius (Italy)

Effects of eruption source parameter variation and meteorological dataset on tephra fallout hazard assessment: example from Vesuvius (Italy)

Assessing future vent opening locations at the Somma‐Vesuvio volcanic complex: 1. A new information geodatabase with uncertainty characterizations

Reconstructing eruptive source parameters from tephra deposit: a numerical study of medium-sized explosive eruptions at Etna volcano

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