86 research outputs found
Glacier melting during lava dome growth at Nevado de Toluca volcano (Mexico): Evidences of a major threat before main eruptive phases at ice-caped volcanoes
When appearances lie: micropedology of palaeosol markers in a Pleistocene sedimentary record from central Po Plain
The 16 November 2006 flank collapse of South-East Crater at Mount Etna, Italy: study of the deposit and hazard assessment
On 16 November 2006 a flank collapse affected the unstable Eastern slope of the South-East Crater
16 (SEC) of Mt. Etna. The collapse occurred during one of the paroxysmal events with sustained strombolian
17 activity that characterized the August-December 2006 eruption and was triggered by erosion of loose,
18 hydrothermally-altered material of the steep south-east sector of SEC from the outpour of lava. The collapse
19 produced a debris avalanche that involved both lithic and juvenile material and resulted in a deposit
20 emplaced on the Eastern flank of the volcano up to 1.2 km away from the source. The total volume of the
21 deposit was estimated to be in the order of 330,000-413,000 m3. The reconstruction of the collapse event
22 was simulated using TITAN2D, software designed to model granular avalanches and landslides. This
23 approach can be used to estimate areas that may be affected by similar collapse events in the future. The
24 area affected by the 16 November 2006 lateral collapse of SEC was a small portion of the Mt. Etna summit
25 area, but the fact that no one was killed or injured should be considered fortuitous. The summit and adjacent
26 areas of the volcano, in fact, are usually visited by many tourists who are not prepared to face this type of
27 danger. The 16 November 2006 collapse points to the need to be prepared for similar events through
28 scientific investigation (analysis of flank instability, numerical simulation of flows) and development of specific
civil protection plans
Land subsidence, Ground Fissures and Buried Faults: InSAR Monitoring of Ciudad Guzmán (Jalisco, Mexico)
We study land subsidence processes and the associated ground fissuring, affecting
an active graben filled by thick unconsolidated deposits by means of InSAR techniques and
fieldwork. On 21 September 2012, Ciudad Guzmán (Jalisco, Mexico) was struck by ground
fissures of about 1.5 km of length, causing the deformation of the roads and the propagation
of fissures in adjacent buildings. The field survey showed that fissures alignment is
coincident with the escarpments produced on 19 September 1985, when a strong earthquake
with magnitude 8.1 struck central Mexico. In order to detect and map the spatio-temporal
features of the processes that led to the 2012 ground fissures, we applied InSAR multitemporal
techniques to process ENVISAT-ASAR and RADARSAT-2 satellite SAR images
acquired between 2003 and 2012. We detect up to 20 mm/year of subsidence of the
northwestern part of Ciudad Guzmán. These incremental movements are consistent with the ground fissures observed in 2012. Based on interferometric results, field data and 2D
numerical model, we suggest that ground deformations and fissuring are due to the presence
of areal subsidence correlated with variable sediment thickness and differential compaction,
partly driven by the exploitation of the aquifers and controlled by the distribution and
position of buried faults
40Ar/39Ar geochronology of Holocene basalts; examples from Stromboli, Italy
Absolute chronologies of active volcanoes and consequently timescales for eruptive behaviour and magma production form a quantitative basis for understanding the risk of volcanoes. Surprisingly, the youngest records in the geological timescale often prove to be the most elusive when it comes to isotopic dating. Absolute Holocene volcanic records almost exclusively rely on
14C ages measured on fossil wood or other forms of biogenic carbon. However, on volcanic flanks, fossil carbon is often not preserved, and of uncertain origin when present in paleosols. Also, low 14C-volcanic CO2 may have mixed with atmospheric and soil 14C-CO2, potentially causing biased ages. Even when reliable data are available, it is important to have independent corroboration of inferred chronologies as can be obtained in principle using the 40K/40Ar decay system. Here we present results of a 40Ar/39Ar dating study of basaltic groundmass in the products from the Pleistocene – Holocene boundary until the beginning of the historic era for the north-northeastern flank of Stromboli, Aeolian Islands, Italy, identifying a short phase of intensified flank effusive activity 7500±500 yrs ago, and a maximum age of 4000±900 yr for the last flank collapse event that might have caused the formation of the Sciara del Fuoco depression. We expect that under optimum conditions 40Ar/39Ar dating of basaltic groundmass samples can be used more widely for dating Holocene volcanic events
Corrigendum to ‘Structural analysis and fluid geochemistry as tools to assess the potential of the Tocomar geothermal system, Central Puna (Argentina)’ [Geothermics Volume 98, January 2022, 102297] (Geothermics (2022) 98, (S0375650521002546), (10.1016/j.geothermics.2021.102297))
Preliminary data on the structure and potential of the Tocomar geothermal field (Puna plateau, Argentina).
AbstractThis study presents new stratigraphic, structural and hydrogeological data on the Tocomar geothermal volcanic area (Puna plateau, Central Andes, NW Argentina), together with preliminary geochemical and magnetotelluric data.The main geothermal reservoir is located within the fractured Pre-Palaeozoic–Ordovician units. The reservoir is recharged by meteoric waters. Geothermal fluids upwell where main regional structures intersect secondary structures associated with the development of the Tocomar basin. Preliminary data indicate a reservoir temperature of ∼ 200° C and a local geothermal gradient of ∼ 130° C/km associated with the Quaternary volcanic activity in the Tocomar area
Gravitational sliding of the Mt. Etna massif along a sloping basement
Geological field evidence and laboratory modelling indicate that volcanoes constructed on slopes slide downhill. If this happens on an active volcano, then the movement will distort deformation data and thus potentially compromise interpretation. Our recent GPS measurements demonstrate that the entire edifice of Mt. Etna is sliding to the ESE, the overall direction of slope of its complex, rough sedimentary basement. We report methods of discriminating the sliding vector from other deformation processes and of measuring its velocity, which averaged 14 mm year−1 during four intervals between 2001 and 2012. Though sliding of one sector of a volcano due to flank instability is widespread and well-known, this is the first time basement sliding of an entire active volcano has been directly observed. This is important because the geological record shows that such sliding volcanoes are prone to devastating sector collapse on the downslope side, and whole volcano migration should be taken into account when assessing future collapse hazard. It is also important in eruption forecasting, as the sliding vector needs to be allowed for when interpreting deformation events that take place above the sliding basement within the superstructure of the active volcano, as might occur with dyke intrusion or inflation/deflation episodes
Reconstruction of the eruptive activity on the NE sector of Stromboli volcano: timing of flank eruptions since 15 ka
A multidisciplinary geological and compositional investigation allowed us to reconstruct the occurrence of flank eruptions on the lower NE flank of Stromboli volcano since 15 ka. The oldest flank eruption recognised is Roisa, which occurred at ~15 ka during the Vancori period, and has transitional compositional characteristics between the Vancori and Neostromboli phases. Roisa was followed by the San Vincenzo eruption that took place at ~12 ka during the early stage of Neostromboli period. The eruptive fissure of San Vincenzo gave rise to a large scoria cone located below the village of Stromboli, and generated a lava flow, most of which lies below sea level. Most of the flank eruptions outside the barren Sciara del Fuoco occurred in a short time, between ~9 and 7 ka during the Neostromboli period, when six eruptive events produced scoria cones, spatter ramparts and lava flows. The Neostromboli products belong to a potassic series (KS), and cluster in two differently evolved groups. After an eruptive pause of ~5,000 years, the most recent flank eruption involving the NE sector of the island occurred during the Recent Stromboli period with the formation of the large, highly K calc-alkaline lava flow field, named San Bartolo. The trend of eruptive fissures since 15 ka ranges from N30°E to N55°E, and corresponds to the magma intrusions radiating from the main feeding system of the volcano
- …