Volcanic hazard and risk assessment in a multi-source volcanic area: the example of Napoli city (Southern Italy)

Alberico, Ines; Petrosino, Paola; Lirer, L.

doi:10.5194/nhess-11-1057-2011

Cited by 48 publications

(33 citation statements)

References 51 publications

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“…By using the distribution of relevant geophysical and geochemical variables in the caldera to quantify the spatial probability of new vent opening, and the energy-line model to determine the areas affected by PDCs, Alberico et al (2002Alberico et al ( , 2011 developed qualitative incursion maps for selected eruptions scaled to VEI. Similarly, Rossano et al (2004) produced first-order quantitative PDC incursion maps by assuming vent opening in the central part of the caldera, and using the simple 1D dynamic model of McEwen and Malin (1989) treating PDCs as homogeneous Bingham fluids.…”

Section: Campi Flegreimentioning

confidence: 99%

Pyroclastic Density Current Hazards and Risk

Neri

Ongaro

Voight

et al. 2015

Volcanic Hazards, Risks and Disasters

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Section: Campi Flegreimentioning

confidence: 99%

Pyroclastic Density Current Hazards and Risk

Neri

Ongaro

Voight

et al. 2015

Volcanic Hazards, Risks and Disasters

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“…The model can therefore approximate the flow front velocity as a function of the distance from the origin. In order to quantify first-order effect of topography on the invasion area, the kinetic energy of the flow front is compared to the potential energy required to overcome the topographical reliefs that the flow encounters, thus following an approach similar to the energy-line (or energy-cone) model (Hsu, 1975;Malin and Sheridan, 1982;Alberico et al, 2011;Tierz et al, 2016). For simplicity the sea surface is assumed as flat ground topography with no effect of the water on the PDC propagation: this enables us to obtain a first (likely minimal) approximation of the potential hazard represented by PDCs traveling over the sea (see Neri et al, 2015, for more details).…”

Section: Simplified Pdc Invasion Modelmentioning

confidence: 99%

“…A qualitative hazard map of PDC invasion for the city of Napoli from both CF and Vesuvius was also developed, based on the integration of a spatial probability map of vent opening and the consideration of different eruptive scales (Alberico et al, 2011). The invasion areas were determined using the energycone model based on the assumption of linear decay of flow energy with distance (e.g., Hsu, 1975;Malin and Sheridan, 1982).…”

Section: Introductionmentioning

confidence: 99%

The Effects of Vent Location, Event Scale, and Time Forecasts on Pyroclastic Density Current Hazard Maps at Campi Flegrei Caldera (Italy)

et al. 2017

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This study presents a new method for producing long-term hazard maps for pyroclastic density currents (PDC) originating at Campi Flegrei caldera. Such method is based on a doubly stochastic approach and is able to combine the uncertainty assessments on the spatial location of the volcanic vent, the size of the flow and the expected time of such an event. The results are obtained by using a Monte Carlo approach and adopting a simplified invasion model based on the box model integral approximation. Temporal assessments are modeled through a Cox-type process including self-excitement effects, based on the eruptive record of the last 15 kyr. Mean and percentile maps of PDC invasion probability are produced, exploring their sensitivity to some sources of uncertainty and to the effects of the dependence between PDC scales and the caldera sector where they originated. Conditional maps representative of PDC originating inside limited zones of the caldera, or of PDC with a limited range of scales are also produced. Finally, the effect of assuming different time windows for the hazard estimates is explored, also including the potential occurrence of a sequence of multiple events. Assuming that the last eruption of Monte Nuovo (A.D. 1538) marked the beginning of a new epoch of activity similar to the previous ones, results of the statistical analysis indicate a mean probability of PDC invasion above 5% in the next 50 years on almost the entire caldera (with a probability peak of ∼25% in the central part of the caldera). In contrast, probability values reduce by a factor of about 3 if the entire eruptive record is considered over the last 15 kyr, i.e., including both eruptive epochs and quiescent periods.

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“…This is especially true in the case of Mount Cameroon. In this context of strong social vulnerability (Apa et al, 2012), the WebGIS has less potential to be useful for people at risk than for national and local authorities concerned with risk management. For local communities at risk, other tools are more appropriate such as participatory 3-D maps (P3DM) for local communities (Cadag and Gaillard, 2012).…”

Section: Lessons Learnt From the Mount Cameroon: Usefulness And Transmentioning

confidence: 99%

“…Risk therefore combines the multiple relevant hazards in a given area, of the exposed assets, their vulnerability and of the capacity of societies to cope with these hazards (e.g. Marzocchi and Woo, 2009;Alberico et al, 2011). Boundary objects in volcanic risk management include, for example, scenarios and hazard and risk maps (e.g.…”

Section: Introductionmentioning

confidence: 99%

WebGIS as boundary tools between scientific geoinformation and disaster risk reduction action in volcanic areas

Cozannet

Bagni²,

Thierry³

et al. 2014

Nat. Hazards Earth Syst. Sci.

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Abstract.As the amount of spatial data is growing, there is increased interest in developing tools to explore, visualize and interpret them, with the final aim of informing decision making efficiently. Within the European MIAVITA project, we examined this issue in the case of volcanic areas, where existing geospatial databases are particularly complex due to the number of threats to be considered, including volcanic (e.g. lava flows, ash fall) and non-volcanic hazards, such as landslides or tsunamis. We involved a group of hazard and risk analysts and managers, civil security officers, GIS analysts and system developers to design a Web-based geographical information system (WebGIS). We tested the system at the Mount Cameroon volcano, taking advantage of a complex hazard and risk geographical database. This study enabled identifying key requirements for such tools in volcanic areas, such as the need to manage user privileges differently according to their profile and the status of the volcano. This work also highlights that, in addition to the development of large geoinformation clearinghouses, there is a need for sitespecific information systems focused on working procedures of users, in order to fill the last gap between data producers and users.

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Volcanic hazard and risk assessment in a multi-source volcanic area: the example of Napoli city (Southern Italy)

Cited by 48 publications

References 51 publications

Pyroclastic Density Current Hazards and Risk

Pyroclastic Density Current Hazards and Risk

The Effects of Vent Location, Event Scale, and Time Forecasts on Pyroclastic Density Current Hazard Maps at Campi Flegrei Caldera (Italy)

WebGIS as boundary tools between scientific geoinformation and disaster risk reduction action in volcanic areas

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