scholarly journals Lava flow hazard map of Piton de la Fournaise volcano 

2021 ◽  
Author(s):  
Oryaëlle Chevrel ◽  
Massimiliano Favalli ◽  
Villeneuve Nicolas ◽  
Andrew Harris ◽  
Alessandro Fornaciai ◽  
...  
Keyword(s):  
Lava Flow ◽  
18Th Century ◽  
Hot Spot ◽  
Hazard Map ◽  
Hazard Maps ◽  
Flow Paths ◽  
Piton De La Fournaise ◽  
Lava Flow Hazard ◽  
Multi Temporal ◽  
Deep Sources

<p>Piton de la Fournaise, situated on La Réunion Island (France), is one of the most active hot spot basaltic shield volcanoes worldwide, experiencing at least two eruptions per year since the establishment of the observatory in 1979. Eruptions are typically fissure-fed and form extensive lava flow fields. About 95 % of some ~250 historical events (since the first confidently dated eruption in 1708) have occurred inside an uninhabited horse-shoe shaped caldera (hereafter referred to as the Enclos) which is open to the ocean on its eastern side. Rarely (12 times since the 18th century), fissures have opened outside of the Enclos where housing units, population centers and infrastructure are at risk. In such a situation, lava flow hazard maps are a useful way of visualizing lava flow inundation probabilities over large areas. Here, we present a lava flow hazard map for Piton de la Fournaise volcano based on: i) vent distribution, ii) statistics of lava flow lengths, iii) lava flow recurrence times, and iv) simulations of lava flow paths across multi-temporal (i.e., regularly updated) topography using the DOWNFLOW stochastic numerical model. A map of the entire volcano highlights that the most probable (up to 12 %) location for future lava flow inundation is within the Enclos, where about 100,000 visitors are present each year. Hazard distribution changes throughout the analysis period due to the high frequency of eruptions that constantly modifies the vent opening distribution as well as the topography and the lava flow dimensional characteristics. Outside of the Enclos, probabilities reach 0.5 % along the well-defined rift zones and, although hazard occurrence in inhabited areas is deemed to be very low (<0.1 %), it may be underestimated here, as our study is only based on post-18th century records and neglects cycles of activity at the volcano. Specific hazard maps considering different event scenarios (i.e., events fed by different combinations of temporally evolving superficial and deep sources) are required to better assess affected areas in the future – especially by atypical, but potentially extremely hazardous, large volume eruptions. At such an active site, our method supports the need for regular updates of DEMs and associated lava flow hazard maps if we are to be effective in mitigating the associated risks.</p>

scholarly journals Lava flow hazard map of Piton de la Fournaise volcano

2020 ◽  
Author(s):  
Magdalena Oryaëlle Chevrel ◽  
Massimiliano Favalli ◽  
Nicolas Villeneuve ◽  
Andrew J. L. Harris ◽  
Alessandro Fornaciai ◽  
...  
Keyword(s):  
Lava Flow ◽  
18Th Century ◽  
Hot Spot ◽  
Hazard Map ◽  
Flow Paths ◽  
Piton De La Fournaise ◽  
Lava Flow Hazard ◽  
Multi Temporal ◽  
La Réunion Island ◽  
Hazard Distribution

Abstract. Piton de la Fournaise, situated on La Réunion Island (France), is one of the most active hot spot basaltic shield volcanoes worldwide, experiencing at least two eruptions per year since the establishment of the observatory in 1979. Eruptions are typically fissure-fed and form extensive lava flow fields. About 95 % of some ~250 historical events (since the first confidently dated eruption in 1708) have occurred inside an uninhabited horse-shoe shaped caldera (hereafter referred to as the Enclos) which is open to the ocean on its eastern side. Rarely (12 times since the 18th century), fissures have opened outside of the Enclos where housing units, population centers and infrastructure are at risk. In such a situation, lava flow hazard maps are a useful way of visualizing lava flow inundation probabilities over large areas. Here, we present a lava flow hazard map for Piton de la Fournaise volcano based on: i) vent distribution, ii) statistics of lava flow lengths, iii) lava flow recurrence times, and iv) simulations of lava flow paths across multi-temporal (i.e., regularly updated) topography using the DOWNFLOW stochastic numerical model. A map of the entire volcano highlights that the most probable (up to 12 %) location for future lava flow inundation is within the Enclos, where about 100,000 visitors are present each year. Hazard distribution changes throughout the analysis period due to the high frequency of eruptions that constantly modifies the vent opening distribution as well as the topography and the lava flow dimensional characteristics. Outside of the Enclos, probabilities reach 0.5 % along the well-defined rift zones and, although hazard occurrence in inhabited areas is deemed to be very low (

scholarly journals Lava flow hazard map of Piton de la Fournaise volcano

2021 ◽  
Vol 21 (8) ◽  
pp. 2355-2377
Author(s):  
Magdalena Oryaëlle Chevrel ◽  
Massimiliano Favalli ◽  
Nicolas Villeneuve ◽  
Andrew J. L. Harris ◽  
Alessandro Fornaciai ◽  
...  
Keyword(s):  
Lava Flow ◽  
Hazard Assessment ◽  
Land Use Planning ◽  
18Th Century ◽  
Hot Spot ◽  
Hazard Map ◽  
Hazard Maps ◽  
Piton De La Fournaise ◽  
Lava Flow Hazard

Abstract. Piton de la Fournaise, situated on La Réunion island (France), is one of the most active hot spot basaltic shield volcanoes worldwide, experiencing at least two eruptions per year since the establishment of the volcanological observatory in 1979. Eruptions are typically fissure-fed and form extensive lava flow fields. About 95 % of some ∼ 250 historical events (since the first confidently dated eruption in 1708) have occurred inside an uninhabited horseshoe-shaped caldera (hereafter referred to as the Enclos), which is open to the ocean on its eastern side. Rarely (12 times since the 18th century), fissures have opened outside of the Enclos, where housing units, population centers, and infrastructure are at risk. In such a situation, lava flow hazard maps are a useful way of visualizing lava flow inundation probabilities over large areas. Here, we present the up-to-date lava flow hazard map for Piton de la Fournaise based on (i) vent distribution, (ii) lava flow recurrence times, (iii) statistics of lava flow lengths, and (iv) simulations of lava flow paths using the DOWNFLOW stochastic numerical model. The map of the entire volcano highlights the spatial distribution probability of future lava flow invasion for the medium to long term (years to decades). It shows that the most probable location for future lava flow is within the Enclos (where there are areas with up to 12 % probability), a location visited by more than 100 000 visitors every year. Outside of the Enclos, probabilities reach 0.5 % along the active rift zones. Although lava flow hazard occurrence in inhabited areas is deemed to be very low (< 0.1 %), it may be underestimated as our study is only based on post-18th century records and neglects older events. We also provide a series of lava flow hazard maps inside the Enclos, computed on a multi-temporal (i.e., regularly updated) topography. Although hazard distribution remains broadly the same over time, some changes are noticed throughout the analyzed periods due to improved digital elevation model (DEM) resolution, the high frequency of eruptions that constantly modifies the topography, and the lava flow dimensional characteristics and paths. The lava flow hazard map for Piton de la Fournaise presented here is reliable and trustworthy for long-term hazard assessment and land use planning and management. Specific hazard maps for short-term hazard assessment (e.g., for responding to volcanic crises) or considering the cycles of activity at the volcano and different event scenarios (i.e., events fed by different combinations of temporally evolving superficial and deep sources) are required for further assessment of affected areas in the future – especially by atypical but potentially extremely hazardous large-volume eruptions. At such an active site, our method supports the need for regular updates of DEMs and associated lava flow hazard maps if we are to be effective in keeping up to date with mitigation of the associated risks.

Fast short-term lava flow hazard assessment with graph theory

2020 ◽  
Author(s):  
Veronica Centorrino ◽  
Giuseppe Bilotta ◽  
Annalisa Cappello ◽  
Gaetana Ganci ◽  
Claudia Corradino ◽  
...  
Keyword(s):  
Graph Theory ◽  
Lava Flow ◽  
Graph Representation ◽  
Computational Time ◽  
Hazard Map ◽  
Short Term ◽  
Flow Paths ◽  
Lava Flow Hazard ◽  
Mt Etna

&lt;p&gt;We explore the use of graph theory to assess short-term hazard of lava flow inundation, with Mt Etna as a case study. In the preparation stage, we convert into a graph the long-term hazard map produced using about 30,000 possible eruptive scenarios calculated by simulating lava flow paths with the physics-based MAGFLOW model. Cells in the original DEM-based representation are merged into graph vertices if reached by the same scenarios, and for each pair of vertices, a directed edge is defined, with an associated lava conductance (probability of lava flowing from one vertex to the other) computed from the number of scenarios that reach both the start and end vertex. In the application stage, the graph representation can be used to extract short-term lava flow hazard maps in case of unrest. When a potential vent opening area is identified e.g. from monitoring data, the corresponding vertices in the graph are activated, and the information about lava inundation probability is iteratively propagated to neighboring vertices through the edges, weighted according to the associated lava conductance. This allows quick identification of potentially inundated areas with little computational time. A comparison with the deterministic approach of subsetting and recomputing the weights in the long-term hazard map is also presented to illustrate benefits and downsides of the graph-based approach.&lt;/p&gt;

Supplementary material to "Lava flow hazard map of Piton de la Fournaise volcano"

2020 ◽  
Author(s):  
Magdalena Oryaëlle Chevrel ◽  
Massimiliano Favalli ◽  
Nicolas Villeneuve ◽  
Andrew J. L. Harris ◽  
Alessandro Fornaciai ◽  
...  
Keyword(s):  
Lava Flow ◽  
Hazard Map ◽  
Piton De La Fournaise ◽  
Lava Flow Hazard ◽  
Supplementary Material

scholarly journals Retrospective validation of a lava-flow hazard map for Mount Etna volcano

2011 ◽  
Vol 54 (5) ◽  
Author(s):  
Annalisa Cappello ◽  
Annamaria Vicari ◽  
Ciro Del Negro
Keyword(s):  
Lava Flow ◽  
Mount Etna ◽  
Hazard Map ◽  
Etna Volcano ◽  
Lava Flow Hazard

scholarly journals Lava flow hazard at Fogo Volcano, Cabo Verde, before and after the 2014–2015 eruption

2016 ◽  
Vol 16 (8) ◽  
pp. 1925-1951 ◽  
Author(s):  
Nicole Richter ◽  
Massimiliano Favalli ◽  
Elske de Zeeuw-van Dalfsen ◽  
Alessandro Fornaciai ◽  
Rui Manuel da Silva Fernandes ◽  
...  
Keyword(s):  
Lava Flow ◽  
Emergency Preparedness ◽  
Disaster Response ◽  
Flow Simulations ◽  
Cabo Verde ◽  
Topographic Information ◽  
Lava Flow Hazard ◽  
Before And After ◽  
Lava Flow Emplacement ◽  
Fogo Volcano

Abstract. Lava flow simulations help to better understand volcanic hazards and may assist emergency preparedness at active volcanoes. We demonstrate that at Fogo Volcano, Cabo Verde, such simulations can explain the 2014–2015 lava flow crisis and therefore provide a valuable base to better prepare for the next inevitable eruption. We conducted topographic mapping in the field and a satellite-based remote sensing analysis. We produced the first topographic model of the 2014–2015 lava flow from combined terrestrial laser scanner (TLS) and photogrammetric data. This high-resolution topographic information facilitates lava flow volume estimates of 43.7 ± 5.2 × 106 m3 from the vertical difference between pre- and posteruptive topographies. Both the pre-eruptive and updated digital elevation models (DEMs) serve as the fundamental input data for lava flow simulations using the well-established DOWNFLOW algorithm. Based on thousands of simulations, we assess the lava flow hazard before and after the 2014–2015 eruption. We find that, although the lava flow hazard has changed significantly, it remains high at the locations of two villages that were destroyed during this eruption. This result is of particular importance as villagers have already started to rebuild the settlements. We also analysed satellite radar imagery acquired by the German TerraSAR-X (TSX) satellite to map lava flow emplacement over time. We obtain the lava flow boundaries every 6 to 11 days during the eruption, which assists the interpretation and evaluation of the lava flow model performance. Our results highlight the fact that lava flow hazards change as a result of modifications of the local topography due to lava flow emplacement. This implies the need for up-to-date topographic information in order to assess lava flow hazards. We also emphasize that areas that were once overrun by lava flows are not necessarily safer, even if local lava flow thicknesses exceed the average lava flow thickness. Our observations will be important for the next eruption of Fogo Volcano and have implications for future lava flow crises and disaster response efforts at basaltic volcanoes elsewhere in the world.

scholarly journals Determination of Primary and Secondary Lahar Flow Paths of the Fuego Volcano (Guatemala) Using Morphometric Parameters

2019 ◽  
Vol 11 (6) ◽  
pp. 727 ◽  
Author(s):  
Marcelo Cando-Jácome ◽  
Antonio Martínez-Graña
Keyword(s):  
Shallow Landslide ◽  
Pyroclastic Flows ◽  
Economic Losses ◽  
Hazard Maps ◽  
Topographic Wetness Index ◽  
Flow Paths ◽  
Differential Interferometry ◽  
Fuego Volcano ◽  
Morphological Indices

On 3 June 2018, a strong eruption of the Fuego volcano in Guatemala produced a dense cloud of 10-km-high volcanic ash and destructive pyroclastic flows that caused nearly 200 deaths and huge economic losses in the region. Subsequently, due to heavy rains, destructive secondary lahars were produced, which were not plotted on the hazard maps using the LAHAR Z software. In this work we propose to complement the mapping of this type of lahars using remote-sensing (Differential Interferometry, DINSAR) in Sentinel images 1A and 2A, to locate areas of deformation of the relief on the flanks of the volcano, areas that are possibly origin of these lahars. To determine the trajectory of the lahars, parameters and morphological indices were analyzed with the software System for Automated Geoscientific Analysis (SAGA). The parameters and morphological indices used were the accumulation of flow (FCC), the topographic wetness index (TWI), the length-magnitude factor of the slope (LS). Finally, a slope stability analysis was performed using the Shallow Landslide Susceptibility software (SHALSTAB) based on the Mohr–Coulomb theory and its parameters: internal soil saturation degree and effective precipitation, parameters required to destabilize a hillside. In this case, the application of this complementary methodology provided a more accurate response of the areas destroyed by primary and secondary lahars in the vicinity of the volcano.

A lava flow simulation model for the development of volcanic hazard maps for Mount Etna (Italy)

2006 ◽  
Vol 32 (4) ◽  
pp. 512-526 ◽  
Author(s):  
M.L. Damiani ◽  
G. Groppelli ◽  
G. Norini ◽  
E. Bertino ◽  
A. Gigliuto ◽  
...  
Keyword(s):  
Simulation Model ◽  
Lava Flow ◽  
Volcanic Hazard ◽  
Flow Simulation ◽  
Mount Etna ◽  
Hazard Maps ◽  
Lava Flow Simulation
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