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2. Comment on paper: ‘Morphology and compositions of spinel in Pu′u ′Ō′ō lava (1996–1998), Kilauea volcano, Hawaii′—enigmatic discrepancies between lava and gas-based fO2 determinations of Pu′u ′Ō′ō lava
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Gerlach, T.M.
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- 2004
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3. Reply to comment on paper: ‘Morphology and composition of spinel in Pu′u ′O′o lava (1996–1998), Kilauea volcano, Hawaii’—enigmatic discrepancies between lava and gas-based fO2 determinations of Pu′u ′O′o lava
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Roeder, P.L., Thornber, C., and Grant, A.
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- 2004
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4. Comments on the paper: “Geochemistry of fluids from submarine hot springs at Punta de Mita, Nayarit, Mexico” by Y.A. Taran, S. Inguaggiato, M. Marin, and L.M. Yurova
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Prol-Ledesma, R.M.
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- 2003
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5. How residents and volcanoes co-produce risk knowledge: Ways of knowing and affective attunement to the rhythms of Lonquimay volcano, Chile.
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Vergara-Pinto, Francisca, O'Grady, Nathaniel, Fredriksen, Aurora, Romero, Jorge E., Marchant, Carla, Walshe, Rory, Donovan, Amy, Morin, Julie, and Szlam, Malena
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VOLCANISM , *RISK perception , *VOLCANOES , *LOCAL knowledge , *SEMI-structured interviews - Abstract
In this paper, we present our understanding of the importance of affects in people's sense-making of volcanic risk in everyday life. In doing so, we explore how local knowledge on volcanism is produced and circulated through communities' ongoing affective encounters with volcanoes. Through ethnographic fieldwork and semi-structured interviews, we draw on the heterogeneous experiences and narratives of Malalcahuello residents living next to the Lonquimay volcanic complex in the Southern Andes of Chile. Its last eruption in 1988–1990 formed a new cone on the NE flank, called Navidad (Christmas), which has allowed residents to experience active volcanism in a twofold sense: being affected by its impacts during the eruption, and responding affectively to the volcano in everyday life. The results pave the way for a typology of affect-based ways of knowing volcanism. These are constituted by multiple people's viewpoints: 1) knowing the ground, 2) knowing the territory, 3) knowing the risk, and 4) knowing the behaviour. These ways of knowing vary according to, and are in part determined by, the different rhythms of the volcano itself. Therefore, active volcanism becomes a more-than-human agent of knowledge through its rhythmic presence in people's everyday lives. Over time, the local population has become affectively attuned to both 'hazardous situations' related to volcanic eruption and 'risk and safe situations' during volcanic quiescence. These attributes of human-volcano encounters turn hazardous spaces into affect-laden spaces at different times, raising the need to rethink spatio-temporal dimensions in knowledge dialogue and disaster risk reduction. Overall, the paper underlines the importance of affect-oriented risk research in Chile and worldwide to account for the pre-existent viewpoints from which a volcano is at the heart of people's concerns. • Local communities produce forms of knowledge through their affective encounter with volcanoes. • These ways of knowing comprise the entanglement of knowledge, practices, beliefs, and emotions. • Knowledge and emotional evocations co-emerge rhythmically when interacting with volcanoes. • Volcanic affects are pivotal in the community's awareness of volcanic risk. [ABSTRACT FROM AUTHOR]
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- 2024
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6. Comments on the paper “Is the track of the Yellowstone hotspot driven by a deep mantle plume? — Review of volcanism, faulting, and uplift in light of new data” by Kenneth Pierce and Lisa Morgan [J. Volcanol. Geotherm. Res. 188 (2009), 1–25]
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Hershler, Robert and Liu, Hsiu-Ping
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- 2011
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7. Reply to the comment on the paper “Is the track of the Yellowstone hotspot driven by a deep mantle plume?—Review of volcanism, faulting, and uplift in light of new data”
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Pierce, Kenneth L. and Morgan, Lisa A.
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- 2011
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8. Comments on the paper “Automatic detection and discrimination of volcanic tremors and tectonic earthquakes: An application to Ambrym volcano, Vanuatu” by Daniel Rouland, Denis Legrand, Mikhail Zhizhin and Sylvie Vergniolle [J. Volcanol. Geotherm. Res. 181(2009), 196-206]
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Carniel, Roberto
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- 2010
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9. Comment on paper: Magnetic fabric and inferred flow direction of dikes, conesheets and sill swarms, Isle of Skye, Scotland
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Aubourg, C. and Geoffroy, L.
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- 2003
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10. Source analysis of low frequency seismicity at Mt. Vesuvius by a hybrid moment tensor inversion.
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Manzo, R., Cesca, S., Galluzzo, D., La Rocca, M., Picozzi, M., and Di Maio, R.
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FREQUENCY spectra , *SEISMOLOGY , *EARTHQUAKES , *HETEROGENEITY , *VOLCANOES - Abstract
Seismicity at Mt. Vesuvius has been relatively weak in the last decades. While the occurrence of shallow volcano-tectonic (VT) events at Mt. Vesuvius is well known, the occurrence of deeper low frequency events (LF) was only recently recognized. Previous source studies only targeted VT events, which were found to have quite heterogeneous focal mechanisms. In this paper, we perform for the first time the source inversion of LF seismicity at Mt. Vesuvius, analysing 27 LF events recorded from 2012 to 2021 with the aim to investigate their source processes. Given the challenges of analysing weak LF earthquakes, we implement a specific moment tensor (MT) inversion approach that combines the fit of displacement seismograms in the time domain and amplitude spectra in the frequency domain. The inversion is simultaneously performed for the source depth and moment tensor components in the 2–7 and 2–5 Hz frequency band, assuming either a full or deviatoric MT representation. Source parameter uncertainties are estimated by using a Bayesian bootstrapping scheme. Our results confirm a larger depth of LF events compared to VTs and show a strong heterogeneity of the LF seismic sources, which present various rupture types, different orientations and heterogeneous, whilst poorly resolved, non-double-couple components. The MT variability is qualitatively confirmed by significant differences among the recorded waveforms. The heterogeneity of both VT and LF source processes is attributed to complex source processes in a highly fractured seismogenic volume submitted to a heterogeneous stress field. • The first moment tensor inversion study of LF seismic events at Mt. Vesuvius. • LF seismic events at Mt. Vesuvius occured at depths between 4 and 8 km b.s.l and have characterized by Mw < 2. • A strong heterogeneity in the fault geometry and the driving stress field characterizes LF seismicity of Mt. Vesuvius in the last 30 years. [ABSTRACT FROM AUTHOR]
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- 2024
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11. Results of the CO2 diffuse degassing survey from the 2017 IAVCEI CCVG 13th volcanic gas workshop: Pululahua Dome Complex, Ecuador.
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Lamberti, M.C., Sierra, D., Cardellini, C., Viveiros, F., Vásconez Müller, A., Vasconez, F.J., Narváez, D.F., Silva, C., Melián, G., Caliro, S., Kis, B.M., Ionescu, A., and Hidalgo, S.
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INTERNAL structure of the Earth , *SOIL temperature measurement , *CARBON emissions , *LAVA domes , *VOLCANIC gases - Abstract
Pululahua is a potentially active andesite and dacite lava dome complex. This paper presents the results of a survey focused on carbon dioxide (CO 2) diffuse degassing at Pululahua, which was conducted during the 2017 International Association of Volcanology and Chemistry of the Earth's Interior (IAVCEI) Commission of the Chemistry of Volcanic Gases (CCVG) 13th Gas Workshop. Our objective was to conduct a comprehensive investigation of CO 2 diffuse degassing by employing standard methods for measuring CO 2 flux and temperature, and data processing. These methods were applied to map the spatial distribution of the measured parameters, investigate the origin of CO 2 , and quantify the volcanic CO 2 output within the surveyed area of Pululahua. We carried out a total of 350 soil CO 2 flux and 329 soil temperature measurements and collected 12 gas samples for carbon isotopic composition analysis, surrounding the three youngest domes in the complex. In addition, seventeen CO 2 flux measurements over a thermal water pool were performed. Our findings indicate that the diffuse emission at Pululahua's crater floor is fed by both biogenic and volcanic CO 2. Fluxes from each source are similar in magnitude, with approximately 90% of the measurements falling into an intermediate flux range. The occurrence of volcanic CO 2 emissions is supported by the carbon isotopic composition. Diffuse degassing distribution highlights a CO 2 anomaly surrounding the younger domes within the crater. We estimated the CO 2 diffuse emission using both statistical and geostatistical approaches over area of 3.36 km2, resulting in values of 154.2 t d−1 and 126.2 t d−1 respectively. Based on the geostatistical quantification of the total CO 2 emission from soil degassing, Pululahua's crater volcanic CO 2 contribution is estimated between 59 and 97 t d−1. Finally, the potential hazards associated with the release of cold CO 2 at Pululahua's crater are also discussed. • Pululahua emits volcanic CO 2 diffuse degassing from its crater. • Diffuse degassing structures form a circular shape around the youngest domes. • Carbon isotopic composition of CO 2 indicates both biological and volcanic sources. • Volcanic output is 59–97 t d−1, based on criteria for subtracting biological CO 2. • Probability map of fluxes above the biogenic threshold approximates a hazard map. [ABSTRACT FROM AUTHOR]
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- 2024
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12. Temporal characteristics of a 6.2 Ma-long ash-fall history in the NW Pacific.
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Zelenin, Egor, Garipova, Sofia, Ponomareva, Vera, Portnyagin, Maxim, and Dolgaya, Anna
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GLACIAL Epoch , *FRACTAL analysis , *POISSON processes , *FRACTAL dimensions , *TIME series analysis , *EXPLOSIVE volcanic eruptions - Abstract
Explosive volcanism is one of the most dangerous and far-reaching natural hazards. The largest eruptions are the rarest, so studies of their temporal patterns have to rely on long archives. In this paper, we apply fractal and spectral analyses to the 6.2 Ma-long record of ash-falls at the Detroit Seamount (DS6M), > 600 km east of the Kamchatka Peninsula, NW Pacific, combined with a terrestrial record for the last 30 ka (T30ka). These datasets are the most complete for volcanism in the North Pacific, and DS6M spans all Pleistocene glaciations. In both datasets, events are grouped (Weibull parameter k < 0.84) with no characteristic scale of grouping in the time domain of thousands to millions of years. The fractal dimension of the studied data below the unity may be intrinsic to the volcanism (e.g. as a proxy of fractal composition and topography of a subducting plate) or represent uneven deposition and recovery of tephra. Only for the last 700 ka of DS6M, an increase in the correlation dimension values suggests the applicability of spectral analysis; however, no Milankovitch frequencies have been detected in this dataset. When compared to other North Pacific data for areas repeatedly glaciated in the Middle and Late Pleistocene and to a climate proxy of 18O isotopic stack LR04, the studied data suggest that variation in timing of ash-falls among the sites predominates over hemispheric-scale climatic forcing. If so, Quaternary glaciations had a limited effect on the timing of large explosive eruptions in North Pacific, still affecting the transit and deposition of erupted material. • Irregularities in long (30 ka to 6.2 Ma) records of Kamchatka volcanism have been studied. • The grouping of eruptions is more pronounced than in a Poisson process, even with assumed data loss. • Milankovitch frequencies have not been detected in the datasets. • The variation in timing of ash-falls among the North Pacific sites predominates over hemispheric-scale climatic forcing. [ABSTRACT FROM AUTHOR]
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- 2024
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13. Optimal spatial distribution of seismic stations to detect magma migration using the seismic amplitude ratio analysis.
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Espinosa-Ortega, T. and Taisne, B.
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SEISMIC migration , *SEISMIC networks , *SEISMIC arrays , *RATIO analysis , *SEISMOLOGY - Abstract
Magma migrations frequently trigger seismic swarms, resulting in seismic events that overlap in time and hinder real-time phase picking commonly used for hypocenter location. Addressing this challenge, seismic amplitude ratio analysis (SARA) allows identification of seismic migrations in real-time by simply tracking the relative seismic amplitude between a pair of seismic stations. This paper aims to identify key statistical features of the seismic network array locations that improve their ability to detect seismic migrations using SARA. We evaluated the capability to detect the most frequently oriented magma migrations in over 100 volcanoes, using a criterion previously proposed to study vertical magma migrations in Piton de la Fournaise. Additionally, we investigate the influence of vent-station proximity on magma conduit coverage and identify the distance ratio that yields improved detection. Furthermore, we estimate the seismic network efficiency by calculating the detection capability volume per station. We then use the random forest regression algorithm to identify which statistical features of the seismic network location contribute more to the efficiency disparity among different volcanoes. Notably, our findings reveal that optimizing seismic network coverage entails maximizing the standard deviation of relative pair station distances, while maintaining a prescribed minimum separation distance between station pairs. Our results reveal important criteria that can be used to optimize seismic network location design. • Optimization of seismic network locations to track magma migrations in real-time. • Calculation of the detection capability across 100+ volcanoes, using the Seismic Amplitude Ratio Analysis. • Identification of which statistical properties of the seismic network's locations impact efficiency more. • Evaluation of how the proximity between vents and stations affects the coverage of magma conduits. [ABSTRACT FROM AUTHOR]
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- 2024
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14. Overview of the eruptions of Sinabung Volcano, 2010 and 2013–present and details of the 2013 phreatomagmatic phase.
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Gunawan, Hendra, Surono, Budianto, Agus, Kristianto, Prambada, Oktory, McCausland, Wendy, Pallister, John, and Iguchi, Masato
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EARTHQUAKES , *LAVA domes , *VOLCANIC eruptions , *EMERGENCY management , *DISASTER relief , *HAZARD mitigation - Abstract
A small phreatic eruption of Sinabung Volcano, North Sumatra on 28 August 2010, at 18:30 local time marked the first eruption in the past ~ 1200 years. The eruption took place from two small vents in the south crater area. Explosions and ash emissions from these vents generated multiple ash plumes that reached altitudes of up to 5 km during early- to mid-September. By the end of September 2010, only low level steam plumes were visible and the alert level was reduced from Level 4 (highest) to Level 3. The 2010 eruption effectively ended at this time. Beginning two days after the initial 2010 eruption, activity of the eruption has been monitored continuously by a telemetered seismic network surrounding the volcano and by remotely sensed observations. This monitoring system was supplemented with a near-field continuous GPS network, beginning in February 2011. Persistent fumarolic emissions continued for almost 3 years following the 2010 eruption, before a new eruption began on 15 September 2013. This eruption continues to the present. The ongoing eruption is divided into 5 major phases: 1) phreatomagmatic phase (July 2013–18 December 2013); 2) first dome and collapse phase with pyroclastic density currents (PDCs; block-and-ash flows and related surges) to south (18 December 2013–10 January 2014); 3) lava-flow and collapse phase (10 January 2014–mid-September 2014); 4) second lava dome and collapse phase with PDCs to south (mid-September 2014–July 2015); 5) lava dome collapse and ash explosion phase with PDCs to southeast and east (August 2015–present). The volcano erupted intermittently during the early phreatomagmatic phase with small vertical ash explosions. Then the eruption became increasingly vigorous with more repetitive and intense vertical ash explosions during late October through November. The first small pyroclastic density currents (PDCs) began on November 1. These pyroclastic flows descended the southeastern flank to a distance of 2 km. Swarms of volcano-tectonic (VT) earthquakes and volcanic tremor lasting hours occurred repeatedly during the phreatomagmatic phase and some of these VT-swarms were followed by explosions. In early December 2013, during the transition between phreatomagmatic and dome-collapse phases, swarms of hybrid earthquakes took place preceding and accompanying dome growth. The first lava dome was observed in satellite images on 18 December near the main crater rim. Partial collapses of the dome produced PDCs beginning on 30 December. Growth of this first lava dome continued into January and was accompanied by additional collapses and PDCs. By about 10 January, the lava had transitioned from a summit dome morphology into a lava flow morphology. The resulting lava flow descended the southeast flank of the volcano, producing flow-front and marginal collapses with associated PCDs. One such flow-flank collapse on 2 February 2014 resulted in a PCD that killed 16. The lava flow phase continued through mid-September 2014, when a second summit lava dome began to grow and collapse, producing PDCs initially to the south and southeast, and then beginning in July 2015 to the east and southeast. The eruption of Sinabung resulted in major impacts on the population of the resort and farming area near the volcano and in the Ginting and Karo Regencies of North Sumatra. Local residents, having not experienced eruptions in their lifetimes, were initially curious and eager to receive any information about the eruption regardless of its source. Various institutions provided information with little coordination, resulting in confusion. With time communications have improved and communities and the responsible governments have become better prepared in dealing with the persistent eruption. The Government of Indonesia has provided funding to support villagers who lived within a 5 km radius danger zone to stay in relocation camps as a permanent relocation area is being identified. Unfortunately, on 21 May 2016, 9 additional fatalities took place in the village of Gamber, within the danger zone, when a dome collapse sent a pyroclastic density current into the area. Throughout the eruption, the volcano has been monitored by the Indonesian Center for Volcanology and Geologic Hazard Mitigation (CVGHM) in partnership with the USGS-USAID Volcano Disaster Assistance Program and the Disaster Prevention Research Institute of Kyoto University. Monitoring techniques have included seismic, geodetic, gas, satellite and field observations, as well as occasional sampling of ash and lava for geochemical analyses. In this paper, we summarize key aspects of the monitoring data, their interpretations and their use in forecasting eruptive behavior and in issuance of alerts and warnings. More detailed interpretations of the monitoring data and their use are found in other papers of this special issue. • In this introductory paper to the Special Issue on the eruptions of Sinabung and Kelud volcanoes, we focus on the 2010 and 2013–present eruptions of Sinabung volcano, North Sumatra, Indonesia. • We provide information on the monitoring system used and we highlight how the monitoring data (seismic, geodetic, gas and observations) were used to forecast activity and to issue alerts and warnings. • We also describe the chronology of the 2013-present eruption and we review how the eruption has impacted the lives of residents of the region. [ABSTRACT FROM AUTHOR]
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- 2019
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15. Petrogenesis of Miocene volcanism in the Central Anatolia: Geochemical, isotopic and geochronological evidence.
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Özdamar, Şenel, Billor, Mehmet Z., Sarıkaya, Oral, Şans, Bala Ekinci, Yıldız, Taşkın Deniz, Esenli, Fahri, Zou, Haibo, Sherlock, Sarah, and Gültekin, Ali Haydar
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RARE earth metals , *VOLCANISM , *MIOCENE Epoch , *VOLCANOLOGY , *PETROGENESIS , *VOLCANIC ash, tuff, etc. - Abstract
This paper presents the first 40Ar/39Ar age data, new bulk-rock major-trace element compositions and Nd Sr isotope geochemistry, combined with detailed geological mapping of Galatia Volcanic Province (GVP) in the northwest Central Anatolia (Turkey). Here, there are voluminous extrusive rocks in a wide compositional range: a basalt, andesite and trachyte suite, and their pyroclastic equivalents. 40Ar/39Ar dating of two whole-rock samples from the GVP yielded plateau ages of 21.76 ± 0.8 Ma and 20.97 ± 0.5 Ma, constrain the volcanic activity at ca. 21 Ma (Aquitanian). The samples show by sub-parallel light rare earth element (LREE)-enrichment and relatively flat heavy rare earth element (HREE) patterns and moderate fractionation [average (La/Yb) N = 13.5]. Their initial 87/86Sr values vary between 0.704619 and 0.704998, while initial 143/144Nd values lie between 0.512673 and 0.512755. Integration of the geochemical and geochronological with geological data we propose that the volcanic rocks in the northern area of GVP with calc-alkaline affinity were produced by a lithospheric mantle magma in an extensional setting. • The volcanics erupted the earliest Miocene (Aquitanian). • The volcanism took place in an active continental arc. • FC and minor crustal contamination played role in their evolution. [ABSTRACT FROM AUTHOR]
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- 2024
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16. Explosion mechanism and volume estimation of volcanic ash during the eruption of Sinabung Volcano on February 19, 2018: Insight from kinematic GPS and seismic data.
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Kriswati, Estu, Meilano, Irwan, Hasib, Mohammad, Saepuloh, Asep, Kuncoro, Henri, Dewanto, Bondan Galih, and Fuadi, Azhar
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VOLCANIC eruptions , *VOLCANIC ash, tuff, etc. , *EXPLOSIVE volcanic eruptions , *LAVA domes , *EXPLOSIONS , *EARTHQUAKES , *SERVER farms (Computer network management) - Abstract
On February 19, 2018, Sinabung Volcano erupted explosively, destroying the lava dome and producing a new crater. This eruption was the largest one since it became active again in 2010. We processed kinematic GPS observation combined with seismic data to analyze the explosion process and calculate the volume change during the deflation stage. The time series from the results of GPS data processing for 12 min shows a pattern of inflation that lasts for 180 s followed by deflation. Observation data is divided into 3 phases of activity. The first and second phases are inflation with pressure source during eruption at a depth of 2.3 km below the summit, followed by the third phase of deflation at a shallow depth. The hypocenter of explosion earthquake also in the depth of 2.3 km beneath the crater. This study provides information about the magma dynamics during and after the eruption of Sinabung Volcano. The volume change of inflation and deflation calculated approximately 3 × 106 m3 and − 2.2 × 106 m3, respectively. The ash weight produced by the February 19, 2018 eruption from seismic and ground deformation during the deflation period is approximately 5.6 million tons or 0.006 km3, equivalent with VEI 2 Sinabung eruption. • This paper determiine the volume of ash released during an explosion using kinematic GPS and seismic in nearly real-time as effective method to obtain the parameter for the ash fall modeling. • Seismic and ground deformation signals are transmitted every 1 s and the data are sent to the data center within 2 s, making it possible to determine the volume of volcanic ash release in near-real time. • GPS data with a high sampling rate processed using the kinematic method provides results that represent sudden deformation during the volcanic explosion. [ABSTRACT FROM AUTHOR]
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- 2024
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17. New evidence of the Green Tuff deposits and post-caldera, recent explosive volcanic activity at Pantelleria volcano (Sicily Channel, Italy) recorded in near-vent marine areas.
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Romagnoli, C., Giglio, C., Conte, A.M., Cloke-Hayes, A., Garcia, M., Gasparotto, G., and Benetti, S.
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EXPLOSIVE volcanic eruptions , *VOLCANIC ash, tuff, etc. , *VOLCANOES , *PUMICE , *TEPHROCHRONOLOGY , *MARINE sediments - Abstract
The record of the explosive activity of Pantelleria volcano is well documented by several distal tephra collected in various areas in and around the Mediterranean, while few tephrochronological studies exist on proximal marine areas. In this paper, we investigate three selected coring sites from the northern shoulder of the Pantelleria graben, about 15–30 km from the island, in near-vent position with respect to that volcanic source. Our multiproxy analyses revealed nine tephra layers, totally composed of juvenile materials, mostly ash and pumice fragments, as well as a coarse-grained tephra deposit at the bottom of one of the cores. The major element composition of glass shards indicates a very homogeneous geochemical composition for the tephra layers, suggesting their primary origin. Using litho-stratigraphic and paleoenvironmental proxies, we associated the tephra layers to the latest (<∼13.7 ka) explosive activity of Pantelleria. The coarse-grained deposit, instead, due to its distinctive composition is considered to represent the near-vent, marine equivalent of the distal Y-6 tephra layer, related to the ∼45 ka old co-ignimbrite fallout deposit of the Green Tuff event. The geochemical characterization of such deposit, mostly rhyolitic and partly trachytic, appears to enlarge the bimodal composition recorded in other distal tephra (Y-6) reported in the literature, highlighting the potential of near-vent record in providing additional information on the eruptive history. • Marine tephra have been cored in a proximal position with respect to Pantelleria island. • They have been related to the latest (<13.7 ka) explosive activity of Pantelleria volcano. • A further, basal deposit is interpreted as the near-vent, primary marine record of the Green Tuff fallout event. • Its composition appears to enlarge the bimodal composition recorded in other distal tephra. • This might provide better proximal-distal correlations of the GT-related record and of post-GT tephra. [ABSTRACT FROM AUTHOR]
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- 2024
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18. A source-to-surface model of heat and fluid transport in the Taupō Rift, New Zealand.
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Kissling, W.M., Ellis, S., Barker, S.J., and Caldwell, T.G.
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RIFTS (Geology) , *GEOPHYSICAL observations , *TEMPERATURE control , *LOW temperatures , *HEAT flux , *RAYLEIGH number - Abstract
We construct 2-D numerical models of bulk heat and water transport from the mid-crust (10 km depth) to the surface in a 20 km-wide continental rift, based on observations from the Taupō Rift in the central Taupō Volcanic Zone (TVZ) of New Zealand. The model represents a simplified geological setting with two low-permeability basement-like rock-types, the first defining the margins of the rift and the second a distinct 'rifted basement'. The rift is overlain with a 2 km-thick, 20 km-wide layer of shallow volcanic infill. At the base of model there is a 10 km-deep heat source (the 'hotplate') with a specified TVZ-like heat flux of 0.77 Wm−2 and a 'target' average hotplate temperature of 700o to 900 °C, required to maintain the low melt fractions at ∼10 km depth inferred from geophysics. Parameterising the permeability of the rifted basement is a key part of the paper as it enables both the heat flux boundary condition and a temperature constraint to be satisfied at the hotplate. More generally, it allows the flexibility to control the depth of temperature contours which represent proxies for geophysical measurements. It is described as a power-law for log 10 (horizontal component of permeability, kh) with specified values of kh at two depths and a power law exponent as free parameters. Viable models which satisfy all constraints for the hydrothermal system beneath the TVZ rift have a power-law exponent less than ∼0.4, shallow (2 km deep) kh's of 10–14.0 to 10–13.0 m2, and deep (10 km) kh's <10–16.5 m2. The vertical component of the rifted basement permeability, kv, is ten times higher than kh. A generic feature of the models is that irregular, unsteady convection occurs in the upper ∼5 km of the rift. This results in temporal and spatial fluctuations in heat and fluid flow which are interpreted as high-temperature TVZ-like geothermal systems which have temperatures of ca. 300 °C at 2 km depth. Over the nominal simulation time of 3 Myr, approximately 40% of the geothermal systems are clustered within ∼2 km of the rift margins, with the remainder distributed roughly uniformly across the rift. Between the geothermal systems cool recharge from the surface occurs, with temperatures as low as 50 °C occurring at 5 km depth. The models successfully match temperature proxies for the depths of maximum seismicity (450 °C) and shallowest partial melt (> 700 °C) inferred from geophysical observations. Heat transport within the rift is dominated by convection. This is true even at 10 km depth, at the base of the geothermal systems, where kh in the rifted basement approaches 10−17 m2. In this situation, the relatively large value of vertical permeability kv, ∼ 10−16 m2, allows convection to occur. Conductive heat transport dominates in regions ∼1 km in vertical extent immediately above the hotplate and between the geothermal systems. The vigour of the hydrothermal systems is controlled by the permeability of the shallow volcanics, through which all cold surface recharge and hot outflows of fluid occur. Models with low permeability for the shallow volcanics produce longer lasting and higher temperature geothermal systems, and those with high permeability produce fewer and cooler geothermal systems. • We create a 2D source to surface models of the hydrothermal system below the TVZ. • Models with constant basement permeability cannot satisfy geophysical constraints 81. • We parameterise permeability vs depth in the basement rock 58. • The parameterisation allows models to respect temperature proxies for all constraints 85. [ABSTRACT FROM AUTHOR]
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- 2024
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19. Geothermal systems in volcanic arcs: Volcanic characteristics and surface manifestations as indicators of geothermal potential and favorability worldwide.
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Stelling, P., Shevenell, L., Hinz, N., Coolbaugh, M., Melosh, G., and Cumming, W.
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ISLAND arcs , *VOLCANIC eruptions , *PLEISTOCENE Epoch , *CALDERAS , *FELSIC rocks - Abstract
This paper brings a global perspective to volcanic arc geothermal assessments by evaluating trends and correlations of volcanic characteristic and surface manifestation data from world power production sites in subduction zone volcanic settings. The focus of the work was to evaluate volcanic centers individually and as a group in these arcs by correlating various geologic characteristics with known potential to host electricity grade geothermal systems at the volcanic centers. A database was developed that describes key geologic factors expected to be indicative of productive geothermal systems in a global training set, which includes all 74 subduction zone volcanic centers world-wide with current or proven power production capability. Importantly, this data set only contains data from subduction zone volcanoes and contains no negative cases, limiting the populations of any statistical groups. Regardless, this is the most robust geothermal benchmark training set for magmatic-heated systems to date that has been made public. The work reported here is part of a larger project that included data collection, evaluation, correlations and weightings, fairway and favorability modeling and mapping, prediction of blind systems, and uncertainty analysis to estimate errors associated with model predictions. This first paper describes volcano characteristics, compositions and eruption ages and trends along with surface manifestation observations and temperatures as they relate to known power producing systems. Our findings show a strong correlation between the presence and size of active flank fumarole areas and installed power production. Additionally, the majority of volcanic characteristics, including long-held anecdotal correlations related to magmatic composition or size, have limited to no correlation with power production potential. Notable exceptions are correlations between greater power yield from geothermal systems associated with older (Pleistocene) caldera systems than systems hosted by Holocene calderas or non-caldera volcanic centers. Power-hosting volcanic centers that have erupted within the last 160 years supply 50% of the global installed geothermal power in subduction zones, and nearly all of these systems are generally mafic (basaltic or andesitic) in average composition. Volcanic centers erupting between 160 and 900 years ago are dominated by felsic volcanic systems, and provide 47% of the global power from volcanic arcs. Only 3% of geothermal power produced in subduction zones are hosted by volcanic center erupting more than 900 years ago. We anticipate that these results may be able to help guide future geothermal exploration efforts. [ABSTRACT FROM AUTHOR]
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- 2016
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20. Automatic detection of volcano-seismic events by modeling state and event duration in hidden Markov models.
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Bhatti, Sohail Masood, Khan, Muhammad Salman, Wuth, Jorge, Huenupan, Fernando, Curilem, Millaray, Franco, Luis, and Yoma, Nestor Becerra
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AUTOMATIC detection in radar , *HIDDEN Markov models , *VOLCANOES , *VOLCANIC activity prediction , *SIGNAL processing - Abstract
In this paper we propose an automatic volcano event detection system based on Hidden Markov Model (HMM) with state and event duration models. Since different volcanic events have different durations, therefore the state and whole event durations learnt from the training data are enforced on the corresponding state and event duration models within the HMM. Seismic signals from the Llaima volcano are used to train the system. Two types of events are employed in this study, Long Period (LP) and Volcano-Tectonic (VT). Experiments show that the standard HMMs can detect the volcano events with high accuracy but generates false positives. The results presented in this paper show that the incorporation of duration modeling can lead to reductions in false positive rate in event detection as high as 31% with a true positive accuracy equal to 94%. Further evaluation of the false positives indicate that the false alarms generated by the system were mostly potential events based on the signal-to-noise ratio criteria recommended by a volcano expert. [ABSTRACT FROM AUTHOR]
- Published
- 2016
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21. The Tolbachik volcanic massif: A review of the petrology, volcanology and eruption history prior to the 2012–2013 eruption.
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Churikova, T.G., Gordeychik, B.N., Edwards, B.R., Ponomareva, V.V., and Zelenin, E.A.
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PETROLOGY , *VOLCANOLOGY , *VOLCANIC eruptions , *GEOLOGICAL time scales , *PLATE tectonics - Abstract
The primary goal of this paper is to summarize all of the published data on the Tolbachik volcanic massif in order to provide a clear framework for the geochronologic, petrologic, geochemical and to a lesser extent the geophysical and tectonic characteristics of the Tolbachik system established prior to the 2012–2013 eruption. The Tolbachik massif forms the southwestern part of the voluminous Klyuchevskoy volcanic group in Kamchatka. The massif includes two large stratovolcanoes, Ostry (“Sharp”) Tolbachik and Plosky (“Flat”) Tolbachik, and a 70 km long zone of the basaltic monogenetic cones that form an arcuate rift-like structure running across the Plosky Tolbachik summit. The Tolbachik massif gained international attention after the 1975–1976 Great Tolbachik Fissure Eruption (GTFE), which was one of the largest eruptions of the 20th century and one of the six largest basaltic fissure eruptions in historical time. By the end of the GTFE, 2.2 km 3 of volcanic products of variable basaltic compositions with MORB-like isotopic characteristics covered an area of > 1000 km 2 . During the following three decades more than 700 papers on various aspects of this eruption have been published both in national and international journals. Although the recent 2012–2013 eruption, which is the main topic of this volume, was not as long as the GTFE in duration or as large in area and volume of the erupted deposits, it brought to the surface a unique volcanic material never found before. In order to understand the data from new eruptions and make significant progress towards a better understanding of the Tolbachik magmatic system it is important to be able to put the new results into the historic context of previous research. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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22. End-to-end LSTM based estimation of volcano event epicenter localization.
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Yoma, Néstor Becerra, Wuth, Jorge, Pinto, Andrés, de Celis, Nicolás, Celis, Jorge, Huenupan, Fernando, and Fustos-Toribio, Ivo Janos
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CONVOLUTIONAL neural networks , *INSPECTION & review - Abstract
Locating sources of volcano-seismic event is very relevant to monitor and comprehend volcanic processes. Ordinary estimation of source seismic events is based on phase picking. The most accurate procedure of phase selection is the visual inspection of the records by experts, who employ local characteristics for phase detection and comparison with observed signals from other stations. This activity is highly time demanding, which in turn is a strong motivation to automatize the epicenter estimation process. However, automatic phase picking in volcano signals is highly inaccurate because of the short distances between the event epicenters and the seismograph stations. In this paper, an end-to-end based LSTM (Long-Short Term Memory) scheme is proposed to address the problem of volcano event localization without any a priori model relating phase picking with localization estimation. LSTM was chosen due to its capability to capture the dynamics of time varying signals, and to remove or add information within the memory cell state and model long-term dependencies. A brief insight into LSTM is also discussed here to justify the use of this neural network. The results presented in this paper show that the LSTM based architecture provided a success rate, i.e., an error smaller than 1.0 km, equal to 48.5%, which in turn is dramatically superior to the one delivered by automatic phase picking. Moreover, the proposed end-to-end LSTM based method gave a success rate (18%) higher than CNN (Convolutional Neural Network). The results presented suggest that the approach proposed here for automatic volcano event epicenter localization can be applied to other geophysics problems. • Locating sources of volcano-seismic event is very relevant to monitor active volcanoes and comprehend volcanic processes. • The most accurate procedure of phase selection is the inspection of the records by experts, which is highly time demanding. • Automatic phase picking in volcano signals is highly inaccurate. • In this paper, an end-to-end based LSTM scheme is proposed to address the problem of volcano event localization. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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23. Flank eruptions of Mt Etna during the Greek–Roman and Early Medieval periods: New data from 226Ra–230Th dating and archaeomagnetism.
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Branca, Stefano, Condomines, Michel, and Tanguy, Jean-Claude
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PALEOMAGNETISM , *CINDER cones , *GEOLOGICAL mapping , *LAVA flows - Abstract
In this paper, we present new data from 226 Ra– 230 Th dating and archaeomagnetism with the aim of improving the knowledge of the flank eruptions that occurred at Mt Etna during the Greek–Roman and Early Medieval periods, as defined in the new geological map of the volcano. The combination of the two dating techniques demonstrates that three major flank eruptions occurred on the lower north and west flanks during Greek–Roman epochs, producing large scoria cones and extensive lava flows. In particular, the Mt Ruvolo and Mt Minardo events highly impacted the territory of the west flank, notably by damming the Simeto River. The new data of the Millicucco and Due Monti lava flows, on the lower north–east flank, indicate a younger age than their stratigraphic ages quoted in the 2011 geological map, since they occurred around 700 and 500 AD, respectively. None of the large flank eruptions occurring on the lower slopes of Etna during the Early Medieval age are reported in the historical sources. Overall, our paper shows that a comprehensive assessment of eruptions at Mount Etna in the last three millennia can only be achieved through a multidisciplinary approach. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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24. The "Mera" lahar deposit in the upper Amazon basin: Transformation of a late Pleistocene collapse at Huisla volcano, central Ecuador.
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Espín Bedón, Pedro Alejandro, Mothes, Patricia A., Hall, Minard L., Valverde Arcos, Viviana, and Keen, Hayley
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BRECCIA , *DEBRIS avalanches , *WATERSHEDS , *RIVER channels , *VOLCANOES , *RADIOCARBON dating , *BULK solids - Abstract
The Sub-Andean zone east of the Cordillera Real, Ecuador and out to the Amazon basin's western margin has been the depository of voluminous lahars related to volcanic activity in the Andean highlands. These lahars arrived to the Sub-Andean zone via gravitational transport through narrow river canyons and emplaced volumes surpassing several cubic kilometers over robust inundation zones. This paper discusses the origin, flow route, depositional zone, terrace formation and geomorphic significance of the most important lahar deposit yet mapped in this region, that of the Mera lahar, which likely formed from a late Pleistocene collapse of Huisla volcano, followed by impounding by temporary dams behind drainage-blocking debris avalanche deposits (DAD), then subsequent rupture of the blockage. The actual deposit of the Mera lahar has a thickness between 30 and 70 m, is mainly comprised of DAD breccia, is matrix-supported (c 70%), of reddish gray color and is well-consolidated. Based on geochemical and petrographic similarities, Huisla volcano's DAD is the best candidate for the lahar's source. Huisla volcano is located some 90 km up valley of the bulk of Mera lahar's mapped deposit. Clasts of Mera lahar rocks and Huisla's DAD breccias have 57–61 wt% SiO 2 , corresponding to andesites of the calc-alkaline series with mean values of 1–1.5 wt% for K 2 O. The mapped Mera lahar deposit has an actual volume estimated in 1.2 km3 compared to its original estimated volume of 5.4 km3. Cross-sectional widths of 1.5 to 4.5 km span and extend laterally beyond the actual Pastaza river channel where the lahar's deposition produced high-standing isolated surfaces that are notable local geomorphic features of the upper Sub-Andean zone. The flow modeling program LaharFlow, employing the modern landscape as the topographic base, adequately simulates the flow route and inundation zones of the Mera lahar. • Petrographic fingerprinting shows that Huisla volcano´s DAD breccias provided the bulk clastic material for the Mera lahar. • Huisla volcano had a Pleistocene collapse, possibly from shaking provoked by an active fault under its SW shoulder. Coeval eruptive activity was likely since radially fractured bombs are present in both the Huisla DAD and the Mera lahar deposit. • DAD blockage indeep canyons impounded the river system and temporary dams formed then ruptured and the ensuing mixture of water and breccia formed an enormous secondary lahar (volume ~ 5 km3) that flowed 90 km to the Sub-Andean-western Amazon area. • The lahar deposit is rich in the Huisla DAD breccias, has a high sand content, was a non-cohesive type and did not transform to a hyperconcentrated flow. • The deposit is still well preserved on the left margin of the Pastaza river, where 30-50 m high terraces now host the towns of Mera and Shell, among others. • Mapping was complex due to cover by jungle vegetation and erosion caused by avulsions of the Pastaza river. • The LaharFlow modeling program gave results that show affinity with the field mapping in certain preserved areas, ie Mera and Shell, and also showed where the deposit may have once been, but erosion has erased evidence. • A log was extracted from Mera lahar´s interior and a radio carbon date of > 43.5 ka was obtained. Overlying dated strata (17 ka - 40.5 ka) provide minimum ages for the Mera lahar. • The low profile volcano Huisla with its collapse events provoked a major lahar, whose deposits are clearly recognizable some 40 ka after the event. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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25. Collecting field data in volcanic landscapes using small UAS (sUAS)/drones.
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Jordan, Benjamin R.
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VOLCANIC fields , *DIGITAL maps , *SLOPE stability , *THERMOGRAPHY , *GENERAL stores , *REMOTELY piloted vehicles - Abstract
The last several years have seen a very rapid increase in the development and availability of unmanned aerial vehicles/systems (UAV or UAS), more commonly called "drones." UAS are remotely-operated aerial vehicles that can be fixed-wing planes, helicopters, or aerial systems with multiple propellers. Small versions of UAS, here called "sUAS," in particular, have become so prevalent that they can be easily purchased at general retail stores. This paper seeks to review and summarize the use of sUAS in volcanic research. Given their size, low cost, and relative durability, sUAS provide a light-weight tool platform that is easy to transport to field locations; quick to set-up; and easy to launch, and control. They require very little launch and recovery space. Because of these characteristics, sUAS are useful in collecting immediate and real-time aerial data, especially in remote, inaccessible, dynamic, and/or hazardous, volcanic environments. In volcanic areas, sUAS have been used for mapping, sample collection, thermal imaging, magnetic surveys, slope stability studies, and as platforms for sensors to measure outgassing of CO 2 and SO 2. They are also becoming invaluable for real-time hazard assessment during and after an eruption. They are, however, limited by their flight time, which is greatly affected by wind speeds. Since they are predominately made of plastic, they are also impacted by the high thermal temperatures found in active volcanic areas, which can degrade their structure and performance. With continued technological improvement however, sUAS have the potential to dramatically improve our ability to collect field data. Because of additional natural, technological, and legal challenges related to their use, it is critical that users be aware of, and adhere to, all national and local laws associated with sUAS. • Small drones (sUAS) have become common in field work due to their low cost, durability, ease of use and transport, and as a safe means to access hazardous areas. • sUAS are being used in volcanic areas for a variety of purposes, such as monitoring change over time, assessing hazards, creating digital maps, and sampling gas and tephra. • Although challenges exist with using sUAS, they have become standard tools in volcanological research. • Any research done using sUAS should be done only by following national and local regulations governing their use. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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26. Current knowledge of Etna's flank eruptions (Italy) occurring over the past 2500 years. From the iconographies of the XVII century to modern geological cartography.
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Branca, Stefano and Abate, Tiziana
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CARTOGRAPHY , *VOLCANIC eruptions , *HISTORICAL literacy , *GEOLOGICAL mapping , *LAVA flows , *HISTORY of cartography - Abstract
Knowledge of Etna's eruptions has been profoundly influenced by the illustrations, though these can only provide limited information on the lava flows and their effects on the territory. Indeed, the absence of iconographic sources or again the disparity between the physical reality and the illustrations has led to many gaps and uncertainties that have lasted for centuries. This paper traces the progress of the representations of the historical eruptions of Etna volcano, from the earliest attempts in the 17th century, be they iconographic documents or pictorial illustrations, to the modern geological cartography of 21st century. It seeks to reconstruct the evolution of the history and methods of representing Etnean eruptions, highlighting the crucial steps in the progress of knowledge on the historical flank eruptions. The turning point in the long process of drawing and rendering the eruptions of Etna came with the work of Sartorius von Waltershausen, with the realization of the first geological map of the volcano at a 1:50,000 scale between 1836 and 1843. In this long history of the representations of eruptions, begun in the 17th century, Sartorius' cartography finally overcame the problem of rendering these events in space by inserting the notion of history in the map. What now remained for those engaged in mapping the volcano was to solve the issue of defining the "time" of Etna's historical lava flows. This would be tackled only at the end of the 20th century with a multidisciplinary approach comprising stratigraphy, historiographical studies and the dating of the lavas. In this frame, the present state of the knowledge of the flank eruptions occurring on Etna in the past 2500 year has evidenced that during the Greek-Roman and Medieval epochs up to the 17th century flank eruptions commonly involved the middle-lower slopes, impacting mainly the south sector of the volcano with the location of the eruptive fissure sometimes below 1000 m of altitude. This eruptive behavior of the volcano has been radically modified following the occurrence of the large 1669 eruptions since the opening of the fissures was mainly concentrated in the upper-middle slopes between 1600 m and 2500 m a.s.l. • A marked increase in the illustrations of Etna's eruptions is related to the major 1669 event • Sartorius's geological map remained the enduring benchmark on the knowledge of the eruptive history right up the 1900 • The opening of fissures at low elevation were common during the Ancient and Medieval periods • During the last 340 years, no flank eruptions have occurred below 1000 m of altitude. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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27. Remobilization and eruption of an upper crustal cumulate mush at the Singkut caldera (North Sumatra, Indonesia).
- Author
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Forni, Francesca, Phua, Marcus, Bernard, Olivier, Fellin, Maria Giuditta, Oalmann, Jeffrey, Maden, Colin, Rifai, Hamdi, and Bouvet de Maisonneuve, Caroline
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- *
EXPLOSIVE volcanic eruptions , *URANIUM-lead dating , *CALDERAS , *PLAGIOCLASE , *ZIRCON , *CITIES & towns , *MINERALS - Abstract
Understanding the conditions and timescales of storage and remobilization of magma bodies in the upper crust is key to interpreting the signals of potential reawakening at active volcanoes. In this paper, we provide the first volcanological and petrochronological characterization of the Singkut caldera, a young volcanic system located in northern Sumatra (Indonesia), in close proximity to Medan, one of the country's most popoluous cities. Singkut formed at ∼44 ka during a VEI 6 explosive eruption that deposited at least ∼26 km3 of tephra (dense rock equivalent, DRE). The cataclysmic eruption was preceded by >200 ky of mostly effusive pre-caldera activity and followed by effusive to mildly explosive post-caldera activity. The lavas and pumices have high crystallinity (up to 62% crystals) with andesitic to dacitic bulk-rock composition and rhyolitic glass. Mineral textures and matrix glass compositions indicate resorption of quartz, plagioclase and zircon. Zircon crystallization ages show a complete overlap with the eruption ages in pre-caldera lavas, while a time gap in zircon crystallization (>50 ky) is identified in the caldera-forming tuff and post-caldera lavas. Ti-in-zircon thermometry shows that the Singkut magma body experienced a temperature increase starting approximately upon eruption of the pre-caldera lavas (∼254 ka). Such thermal perturbation determined progressive melting of mineral phases in the cumulate crystal mush, caused the resorption of the youngest zircon domains before the caldera-forming eruption, and hampered zircon crystallization between the caldera-forming eruption and the effusion of the post-caldera lavas (∼16 ka). Our data demonstrate how cumulate melting processes played a key role in leading the volcanic system towards a caldera-forming eruption and controlled the transitions in eruptive style between the effusive phases and the explosive climactic eruption. • Singkut caldera formed at 44 ka during a large explosive eruption (∼26 km3 DRE). • Caldera-forming eruption was preceded by >200 ky of effusive volcanic activity. • Magmas are crystal-rich with textural and geochemical evidence of cumulate melting. • Temperature increase in magma reservoir started upon eruption of pre-caldera lavas. • Cumulate mush rejuvenation was triggered by increasing mafic recharge flux. [ABSTRACT FROM AUTHOR]
- Published
- 2024
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28. Sudden alteration in the seismic behavior of the Domuyo volcanic complex in the southern volcanic backarc zone, Argentina.
- Author
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Godoy, Laura B., Nacif, Silvina, Nacif, Andrés, Christiansen, Rodolfo, Álvarez, Orlando, Gimenez, Mario, and Folguera, Andrés
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SEISMIC event location , *SEISMIC networks , *NEOTECTONICS , *EARTHQUAKE magnitude , *EARTHQUAKES - Abstract
The Domuyo volcanic complex (DVC) and its geothermal field in the retroarc zone of the southern Central Andes of Argentina present reduced seismicity according to different catalogs (USGS and INPRES). However, in 2015/2016, a local project was carried out in the area to describe its seismo-volcanic activity, registering a large number of volcano-tectonic (VT) events (538 VT). Considering there is scarce information on these events, this study focuses on analyzing the Domuyo Volcanic Complex (DVC) to assess its seismicity. Therefore, we installed a local seismological network in the study area and compared results with data registered by other authors. Four seismological networks were used, to obtain a more precise location of the seismic events and calculate the focal mechanisms of earthquakes with magnitudes greater than 2. For the first record of crustal seismicity detected by INPRES the September 10th, 2016 with a Ml 3.3, we calculated the focal mechanism with two possible solutions: a thrust solution with a strike component and a favored normal solution with a strike component. Additionally, we relocated the largest event in the Domuyo region on March 27th, 2019, with a magnitude of 4.4 (NEIC – USGS) and focal mechanism with a normal solution and a small strike component, obtaining a shallower depth of 3.9 km instead of 10 km. The new seismological data used in this paper, correspond to September 10th 2016, and two different time periods, the first comprising continuous data from March to April 2019, when the largest registered earthquake occurred in the Domuyo region, and the second from December 2019 to January 2021. At these periods, registered seismicity had magnitudes Ml between 1.9 and 2.8, and focal depths between 1.8 and 5.2 km. Four of these events count with focal mechanisms with extensional and limited strike-slip components that are tentatively linked to the known neotectonic structures affecting the western slope of the DVC. This seismic sequence agrees with previous proposals in which degasification from a magmatic body at shallow depths constitutes the trigger factor. • First focal mechanisms in Domuyo Volcanic Complex (DVC), with principally normal solution. • DVC from 2016 to 2020 was subject to an extensional deformation. • This deformation is associated with the degasification of a shallow magmatic body. [ABSTRACT FROM AUTHOR]
- Published
- 2023
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29. Tectonically-determined distribution of monogenetic volcanoes in a compressive tectonic regime: An example from the Pannonian continental back-arc system (Central Europe).
- Author
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Hencz, Mátyás, Biró, Tamás, Németh, Károly, Porkoláb, Kristóf, Kovács, István János, Spránitz, Tamás, Cloetingh, Sierd, Szabó, Csaba, and Berkesi, Márta
- Subjects
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VOLCANISM , *VOLCANOES , *VOLCANIC fields , *GEOGRAPHIC information systems , *LITHOSPHERE , *WAREHOUSES - Abstract
This paper presents the results from a geographic information systems (GIS) workflow, which was used to analyze the spatial distribution and temporal evolution of volcanoes in the Mio-Pleistocene monogenetic Bakony-Balaton Highland Volcanic Field (BBHVF), located in the Pannonian Basin, Hungary. Volcanism occurred during the tectonic inversion in a back-arc setting and a compressive/transpressive tectonic regime on the hottest and thinnest lithosphere of continental Europe. The main goal of this study is to clarify the effect of the pre-existing structure of the upper lithosphere in the distribution of the volcanic centers across the volcanic field using an innovative GIS methodology. Orientation of the volcanic field was compared to the orientation of the faults in the BBHVF, and in its larger vicinity, which resulted in correspondence, suggesting the dominance of the SW-NE direction. The directions of the volcanic lineaments fit well to the two main fault directions. The fault-volcano proximity analysis suggests that the fault plane of a thrust fault was an important structural feature during the lifespan of the volcanism. All results suggest that the fault plane of a regionally significant Cretaceous thrust fault (Litér Fault) might have served as a temporary pathway for the ascending magma, whereby (similarly to other, smaller faults) redirecting the magmas causing clustering of the volcanoes. This highlights the importance of major upper crustal structural heterogeneities for magma transport in a compressive tectonic system, especially in the case of active, monogenetic volcanic fields from a volcanic hazard perspective. The present GIS workflow can be effective in analyzing the spatial patterns of the volcanism and its connection with crustal structures at monogenetic volcanic fields worldwide. • Spatial and temporal patterns of monogenetic volcanism were investigated in the Bakony-Balaton Highland Volcanic Field • A wide range of GIS tools was used, such as density distribution, or orientation of volcanic lineaments. • Major inherited structures played a vital role in directing magma transport and clustering volcanic centers. • Volcanic lineaments follow fault geometries, providing further evidence of the tectonic control. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
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30. Sulfur melt in Golovnin Caldera, Kunashir Island, Russia.
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Malyshev, Aleksandr and Malysheva, Lidiia
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GAS condensate reservoirs , *CRATER lakes , *SULFUR , *CALDERAS , *WATER waves , *LAKE sediments , *ALUMINUM foam , *METAL foams - Abstract
The paper considers the formation of native sulfur and sulfides in the bottom sediments of volcanic lakes in the Golovnin Caldera. Our observations and microstructure studies indicate the presence of sulfur melt at the bottom of Kipyaschee Lake. Drops of this melt are carried to the surface of the lake as part of a light gray foam. The significant differences of sulfur spherules in the concentration of sulfide mineralization, in its composition, as well as in the presence or absence of numerous opal inclusions are most simply explained by the capture of droplets in various parts of the sulfur melt and their subsequent movement by a gas stream passing through the melt. The effusions of sulfur melt in 1979 are direct evidence of its existence. Molecular chemical modeling shows that the stability of sulfur condensate in the bottom sediments is controlled by two thermobaric surfaces. The upper is controlled by the beginning of water condensation and a wave of acidity, the lower by the beginning of sulfur condensation. Both surfaces are a consequence of the cooling effect of lake water, and when bottom sediments accumulate, they move following changes in the surface of the lake bottom. Elemental sulfur condensate is formed between these surfaces as a result of forced cooling of endogenous gas flows. This process is most active in crater depressions at the bottom of Golovnin Caldera lakes, where sulfidization of the sulfur melt occurs simultaneously with the condensation of sulfur itself. Gravitational deposition of sulfides in the sulfur melt leads to their enrichment of the root parts of crater depressions, where pyrite ore bodies are formed in real time. [Display omitted] • Our research indicates the presence of sulfur melt at the bottom of Kipyaschee Lake. • The stability of sulfur condensate is controlled by two thermobaric surfaces. • Both surfaces are a consequence of the cooling effect of lake water. • We found no colloidal sulfur in the Golovnin caldera. [ABSTRACT FROM AUTHOR]
- Published
- 2023
- Full Text
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31. Pattern recognition applied to seismic signals of the Llaima volcano (Chile): An analysis of the events' features.
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Curilem, Millaray, Vergara, Jorge, San Martin, Cesar, Fuentealba, Gustavo, Cardona, Carlos, Huenupan, Fernando, Chacón, Max, Khan, M. Salman, Hussein, Walid, and Yoma, Nestor Becerra
- Subjects
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PATTERN recognition systems , *SEISMIC event location , *VOLCANOES , *SUPPORT vector machines , *SIGNAL processing - Abstract
This paper proposes a computer-based classifier to automatically identify four seismic event classes of the Llaima volcano, one of the most active volcanoes in the Southern Andes, situated in the Araucanía Region of Chile. A combination of features that provided good recognition performance in our previous papers concerning the Llaima and Villarica (located 100 km south of Llaima) volcanoes is utilized in order to train the classifiers. These features are extracted from the amplitude, frequency and phase of the seismic signals. Unlike the previous works where fixed length windows were used to obtain the seismic signals, this paper employs signals of variable lengths that span the entire seismic event. The classifiers are implemented using support vector machines. A confidence analysis is also included to improve reliability of the classification. Results indicate that the features used for recognition of the events of Villarica volcano also provide good recognition results for the Llaima volcano, yielding classification exactitude of over 80%. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
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32. Insights into the dynamics of planetary interiors obtained through the study of global distribution of volcanoes I: Empirical calibration on Earth.
- Author
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Cañon-Tapia, Edgardo and Mendoza-Borunda, Ramón
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CALIBRATION , *VOLCANOES , *EARTH (Planet) , *SUBMARINE volcanoes , *PLATE tectonics - Abstract
The distribution of volcanic features is ultimately controlled by processes taking place beneath the surface of a planet. For this reason, characterization of volcano distribution at a global scale can be used to obtain insights concerning dynamic aspects of planetary interiors. Until present, studies of this type have focused on volcanic features of a specific type, or have concentrated on relatively small regions. In this paper, (the first of a series of three papers) we describe the distribution of volcanic features observed over the entire surface of the Earth, combining an extensive database of submarine and subaerial volcanoes. The analysis is based on spatial density contours obtained with the Fisher kernel. Based on an empirical approach that makes no a priori assumptions concerning the number of modes that should characterize the density distribution of volcanism we identified the most significant modes. Using those modes as a base, the relevant distance for the formation of clusters of volcanoes is constrained to be on the order of 100 to 200km. In addition, it is noted that the most significant modes lead to the identification of clusters that outline the most important tectonic margins on Earth without the need of making any ad hoc assumptions. Consequently, we suggest that this method has the potential of yielding insights about the probable occurrence of tectonic features within other planets. [ABSTRACT FROM AUTHOR]
- Published
- 2014
- Full Text
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33. Pyroclastic density currents and local topography as seen with the conveyer model.
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Doronzo, Domenico M. and Dellino, Pierfrancesco
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VOLCANIC ash, tuff, etc. , *DENSITY currents , *MULTIPHASE flow , *EXPLOSIVE volcanic eruptions , *SEDIMENTATION & deposition , *FACIES - Abstract
Abstract: Pyroclastic density currents (PDCs) are multiphase flows generated during explosive volcanic eruptions, and they move down the volcano, and over the surrounding topography. The flow–topography interaction can play a fundamental role in the sedimentary processes, and in the resulting deposit facies architecture, as well as can play a dramatic role in the flow behavior, and in the associated volcanic hazard. This paper aims at discussing the PDC–topography interaction theme from the viewpoint of both deposits and flow structure, by accounting for appropriate literature, and revising the concepts in light of the theoretical conveyer model of Doronzo and Dellino (2013) on sedimentation and deposition in particulate density currents. First the effects, then the causes of the flow–topography interaction are discussed, in order to follow the historical development of theme concepts. The discussion is relative in terms of inertial and forced currents, which are defined on the basis of a dimensionless quantity (SD) representing the conservation of mass. Momentum equation relating depositional unit thickness, flow shear velocity, and density contrast shows that the flow is the cause of PDC motion, whereas the density contrast sustains the momentum, and the deposits are the process effect. In particular, the flow structure is described into three parts, flow–substrate boundary zone, boundary layer (lower part), and wake region (upper part) of the current. The facies architecture of PDC deposits, and the volcanic hazard depend on fluid dynamic and hydraulic behavior represented, in light of the conveyer model, by the balance of sedimentation and deposition rates through transport and erosion (“sedimentation–deposition” ratio, SD). This balance acts between flow–substrate boundary zone and boundary layer. The paper discussion mainly applies to small-to-intermediate volume eruptions. Field and modeling examples of Vulcano tuff cone and Colli Albani maar (Italy) constrain the conveyer model, whereas the literature of very large, ignimbrite-forming eruptions, and stratovolcanism is accounted for theme completeness. The main findings are some relative guidelines on PDC–topography interaction that can be used when modeling the flow, and interpreting the pyroclastic deposits: low SD is typical of inertial currents, whereas high SD is typical of forced currents, which can vary depending on topography. [Copyright &y& Elsevier]
- Published
- 2014
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34. Rain-triggered lahars following the 2010 eruption of Merapi volcano, Indonesia: A major risk.
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de Bélizal, Edouard, Lavigne, Franck, Hadmoko, Danang Sri, Degeai, Jean-Philippe, Dipayana, Gilang Aria, Mutaqin, Bachtiar Wahyu, Marfai, Muh Aris, Coquet, Marie, Mauff, Baptiste Le, Robin, Anne-Kyria, Vidal, Céline, Cholik, Noer, and Aisyah, Nurnaning
- Subjects
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VOLCANIC eruptions , *VOLCANIC ash, tuff, etc. , *DENSITY currents , *GEOMORPHOLOGY , *SEDIMENTOLOGY - Abstract
Abstract: The 2010 VEI 4 eruption of Merapi volcano deposited roughly ten times the volume of pyroclastic materials of the 1994 and 2006 eruptions, and is recognized as one of the most intense eruption since 1872. However, as the eruptive phase is now over, another threat endangers local communities: rain-triggered lahars. Previous papers on lahars at Merapi presented lahar-related risk following small-scale dome-collapse PDCs. Thus the aim of this study is to provide new insights on lahar-related risk following a large scale VEI 4 eruption. The paper highlights the high number of events (240) during the 2010–2011 rainy season (October 2010–May 2011). The frequency of the 2010–2011 lahars is also the most important ever recorded at Merapi. Lahars occurred in almost all drainages located under the active cone, with runout distances exceeding 15km. The geomorphic impacts of lahars on the distal slope of the volcano are then explained as they directly threaten houses and infrastructures: creation of large corridors, avulsions, riverbank erosion and riverbed downcutting are detailed through local scale examples. Related damage is also studied: 860 houses damaged, 14 sabo-dams and 21 bridges destroyed. Sedimentological characteristics of volcaniclastic sediments in lahar corridors are presented, with emphasis on the resource in building material that they represent for local communities. Risk studies should not forget that thousands of people are exposing themselves to lahar hazard when they quarry volcaniclastic sediment on lahar corridors. Finally, the efficient community-based crisis management is explained, and shows how local people organize themselves to manage the risk: 3 fatalities were reported, although lahars reached densely populated areas. To summarize, this study provides an update of lahar risk issues at Merapi, with emphasis on the distal slope of the volcano where lahars had not occurred for 40years, and where lahar corridors were rapidly formed. [Copyright &y& Elsevier]
- Published
- 2013
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35. The rheology of two-phase magmas: A review and analysis.
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Mader, H.M., Llewellin, E.W., and Mueller, S.P.
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RHEOLOGY , *MAGMAS , *CRYSTALS , *IGNEOUS rocks , *PROPERTIES of matter , *EARTH sciences - Abstract
Abstract: We consider the current state of our understanding of the rheology of two-phase magmas, that is suspensions of either bubbles or crystals in a viscous silicate melt. The discussion is restricted to strain-rates at which the suspending melt can be considered Newtonian. We start by considering the range of textures found in magmas and the bubble deformation and particle motions caused by shearing. We then review proposed models for suspensions, focussing on those functions of the form η r = f(ϕ) or that have been most widely used to describe magmatic systems (η r is the relative apparent viscosity of the suspension, ϕ is the volume fraction of the suspended phase, τ is the driving stress, and is the strain-rate). Both theoretical and empirical methods are presented and then compared against the available analogue (i.e. non-magmatic) and magmatic data. The paper contains new data and significant re-analysis of previously published data. We present a new semi-empirical constitutive model for bubble-bearing magmas that is valid for steady and unsteady flow and large strains and strain-rates. This equation utilises a new parameter, the capillarity Cx, that encapsulates the combined effect of shearing and unsteadiness on bubble suspensions. We also present a new scheme for dealing with polydispersivity of bubble suspensions. New data on the rheology of particle suspensions undergoing forced-oscillations are presented. These data show that the Cox–Merz rule only holds for dilute particle suspensions ϕ ≲0.25. A re-analysis of all available experimental data that relate rheology to particle aspect ratio provides distinct curves of maximum packing as a function of aspect ratio for smooth and rough particles with magmatic data lying on the curve appropriate for rough particles. We analyse several rheological datasets of crystal-bearing basaltic magmas and find that they are in good agreement with the constitutive equations derived from analogue data. By contrast, the same equations do not agree well with data for high-viscosity, haplogranitic melts. This may be an effect of fracturing or viscous dissipation within these samples. The paper concludes with a practical ‘rheological recipes’ section giving a step-by-step method for calculating a constitutive equation for a two-phase magmatic suspension and assessing its likely accuracy. [Copyright &y& Elsevier]
- Published
- 2013
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36. The use of belief-based probabilistic methods in volcanology: Scientists' views and implications for risk assessments
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Donovan, Amy, Oppenheimer, Clive, and Bravo, Michael
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VOLCANOLOGY , *RISK assessment , *VOLCANIC activity prediction , *VOLCANOLOGISTS , *SURVEYS - Abstract
Abstract: This paper constitutes a philosophical and social scientific study of expert elicitation in the assessment and management of volcanic risk on Montserrat during the 1995–present volcanic activity. It outlines the broader context of subjective probabilistic methods and then uses a mixed-method approach to analyse the use of these methods in volcanic crises. Data from a global survey of volcanologists regarding the use of statistical methods in hazard assessment are presented. Detailed qualitative data from Montserrat are then discussed, particularly concerning the expert elicitation procedure that was pioneered during the eruptions. These data are analysed and conclusions about the use of these methods in volcanology are drawn. The paper finds that while many volcanologists are open to the use of these methods, there are still some concerns, which are similar to the concerns encountered in the literature on probabilistic and determinist approaches to seismic hazard analysis. [Copyright &y& Elsevier]
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- 2012
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37. A new plumbing system framework for mantle plume-related continental Large Igneous Provinces and their mafic-ultramafic intrusions.
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Ernst, R.E., Liikane, D.A., Jowitt, S.M., Buchan, K.L., and Blanchard, J.A.
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IGNEOUS provinces , *FLOOD basalts , *CLIMATE change , *MAGMAS , *MAGMATISM , *LIPS - Abstract
The magmatic components of continental Large Igneous Provinces (LIPs) include flood basalts and their plumbing system of giant mafic dyke swarms (radiating, linear, and the recently discovered circumferential type), mafic sill provinces, a lower crustal magmatic underplate, mafic-ultramafic (M–UM) intrusions, associated silicic magmatism, and associated carbonatites and kimberlites. This paper proposes a new plumbing system framework for mantle plume-related continental LIPs that incorporates all of these components, and provides a context for addressing key thematic aspects such as tracking magma batches "upstream" and "downstream" and their geochemical evolution, assessing the setting of M-UM intrusions and their economic potential, interpreting deep magmatic component identified by geophysical signatures, and estimating magnitudes of extrusive and intrusive components with climate change implications. This plumbing system model, and its associated implications, needs to be tested against the rapidly improving LIP record. • New plumbing system framework for plume-related continental LIPs • Provides context for tracking magma batches "upstream" and "downstream" in the system • Identifies the setting of different types of mafic-ultramafic intrusions within this plumbing system [ABSTRACT FROM AUTHOR]
- Published
- 2019
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38. Magmatic plumbing systems of the monogenetic volcanic fields: A case study of Tolbachinsky Dol, Kamchatka.
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Kugaenko, Yulia and Volynets, Anna O.
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VOLCANIC fields , *SEISMIC tomography , *VOLCANOLOGY , *VOLCANISM , *VOLCANOES , *MAGMAS - Abstract
Clusters of small-volume volcanoes that individually may be defined as monogenetic, but have interlinked and interconnected plumbing systems, are used to be categorized as monogenetic volcanic fields (MVF). We argue that such volcanic clusters should be distinguished as separate type of volcanism, intermediate between monogenetic and polygenetic. The magma plumbing system structure of the MVF (its complexity and polymagmatic character) is the key argument for the potential separation of them in a classification. To avoid confusion caused by genetic meaning of the used words we suggest using a term "areal volcanism" or "areal volcanic fields" (AVF instead of MVF) as defining this special type of volcanic activity. Here we provide a review of the main characteristic features of one of the largest Holocene AVF, which is active now – the Tolbachik field of cinder cones in the southern part of Klyuchevskaya volcano group (Kamchatka), known in the literature as Tolbachinsky Dol. This paper is focused on the research of magma plumbing system. We consider structural, morphological, geological, geochemical and petrological data on the erupted basalts and their genesis. Specially planned seismic experiments made in 2010–2015 (seismic tomography and microseismic sounding) allowed modeling of the principal elements of the magma plumbing system of Tolbachik AVF. Analysis of the investigations made in this area shows that Tolbachik AVF has a complex, dynamic, variable magmatic feeding system, which can be visualized as a superposition of subvertical and sublateral magma conduits. The contrast composition of the erupted rocks is caused by their different, although genetically connected, magma sources and mixing processes. One of the long-lived eruptive centers of Tolbachik AVF is Plosky Tolbachik stratovolcano, which lost its independent activity and was captured by Tolbachik AVF in Holocene. The AVF formed rejuvenated volcanism using the feeding system of the stratovolcano like an "old anthill". The magma plumbing system characteristics of Tolbachinsky Dol strongly support the idea of separation of AVF from monogenetic volcanism type in the classification. • We combine petrological and geophysical data to study Tolbachik areal volcanic field. • We discuss features of magma supply of Tolbachik historical fissure eruptions. • We show integrated models of magma plumbing system for Tolbachik areal volcanic field. • We argue for classification of areal volcanic fields as separate type of volcanism. [ABSTRACT FROM AUTHOR]
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- 2019
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39. Monitoring, forecasting collapse events, and mapping pyroclastic deposits at Sinabung volcano with satellite imagery.
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Pallister, John, Wessels, Rick, Griswold, Julie, McCausland, Wendy, Kartadinata, Nugraha, Gunawan, Hendra, Budianto, Agus, and Primulyana, Sofyan
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- *
VOLCANIC eruptions , *REMOTE-sensing images , *VOLCANOES , *LAVA domes , *LAVA flows , *VOLCANIC ash, tuff, etc. , *DATA distribution - Abstract
During the ongoing (2013–present) eruption of Sinabung volcano, north Sumatra, we have routinely used a variety of satellite remote sensing data to observe and forecast lava dome and lava flow collapse events, to map the resulting pyroclastic deposits, and to estimate effusion rates. In this paper, we focus on the first two years of the current eruption (September 2013–December 2015), and we summarize major events in 2016. We divide the eruption into 5 major phases: 1) phreatomagmatic (July 2013–18 December 2013), 2) first dome growth and collapse (18 December 2013–10 January 2014), 3) lava-flow (10 January 2014–mid-September 2014), 4) second lava dome and collapse (mid-September 2014–July 2015), 5) lava dome collapse and ash explosion phase (August 2015–present). Throughout the eruption, remotely sensed information has been instrumental in assessing the stability of the lava dome and flow and to forecast collapse events that produce pyroclastic density currents (PDCs: block-and-ash flows, co-ignimbrite surges, and blasts). Forecasts based on remote sensing data in combination with seismic, geodetic and gas-monitoring data have also helped inform decisions related to alert levels and evacuations. Relatively unusual aspects of the Sinabung eruption include the transition from dome to flow morphology (phase 2 to phase 3 transition) and the frequent occurrence during phase 3 of collapses from the lava flow-front and flow-margins—collapses that produced extensive pyroclastic density currents. By analogy to the well-known "Merapi type" collapses and pyroclastic deposits, we propose that lava flow-front and flow-margin collapses with associated PDCs be known as "Sinabung type." Although detailed study of deposits has not been possible due to continuing hazards, our observations suggest that the transition from lava dome to lava flow and the occurrence of flow-front and flow-margin collapses reflect a particular combination of lava viscosity and steepness of slope. Our observations also show clear evidence of at least one slope-parallel high-velocity and dilute PDC (a "blast") that emanated from a lava-margin collapse site 500 m downslope from the vent. This 1 February 2014 blast downed and singed a forest out to at least 3.9 km from the collapse site and killed 16 people. We also use a combination of field and remotely sensed data to map the distribution of Sinabung deposits. We estimate eruptive volumes and extrusion rates by combining sequential measurements of lava surface and pyroclastic flow areas with thickness estimates derived from simple geometric assumptions, oblique photographs and Digital Elevation Models (DEMs) derived from remotely sensed data. Our estimates of short-term effusion rates vary widely on a daily to weekly basis, from <1 to >20 m3 s−1. In a few cases, periods of increased extrusion precede lava flow-front collapses by a few days to a week, suggesting delays in transmittance of effusion pulses as lava moves from vent to flow front. We find that, as of 1 January 2016, the total area of deposits is 107 m2, and their approximate deposit volume is about 0.3 km3, equivalent to 0.2 km3 Dense Rock Equivalent (DRE). We anticipate that our deposit maps will be valuable in the future as a framework for the study of the magmatic and textural evolution of eruptive products through time. • Satellite remote sensing was used with and ground-based monitoring was used to issue warnings and reduce risk during the eruption of Sinabung volcano. • Eruption rates and volumes and distribution of lava and pyroclastic deposits were determined with remote sensing. • Unusual lava flow front and margin collapses were deadly; eruptions with these types of collapses are deemed "Sinabung type." [ABSTRACT FROM AUTHOR]
- Published
- 2019
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40. Detection of pre-eruptive seismic velocity variations at an andesitic volcano using ambient noise correlation on 3-component stations: Ubinas volcano, Peru, 2014.
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Machacca-Puma, Roger, Lesage, Philippe, Larose, Eric, Lacroix, Pascal, and Anccasi-Figueroa, Rosa M.
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SURFACE waves (Seismic waves) , *SEISMIC wave velocity , *VOLCANIC eruptions , *VOLCANOES , *SEISMIC waves , *MICROSEISMS , *NOISE - Abstract
Volcano monitoring and eruption forecasting are based on the observation and joined interpretation of several precursory phenomena. It is thus important to detect new types of precursor and to study their relationship with forthcoming eruptions. In the last years, variations of seismic velocity have been observed in some volcanoes, mainly basaltic, before eruptions. In this paper, we look for velocity variations and waveform decorrelations before the 2014 eruptive sequence of the andesitic Ubinas volcano in Peru. We compute velocity changes by using seismic ambient noise cross-correlation (between pairs of stations) and cross-components correlation (between vertical and horizontal components of single stations), as well as coda wave interferometry of seismic multiplets. With these different approaches, we show that the major explosions that occurred from 13 to 19 April were preceded by a clear velocity decrease and waveform decorrelation. The amplitude of velocity change is generally larger on single-station cross-components correlation than on two-station cross-correlation in all the frequency ranges tested (between 0.1 and 8 Hz). We highlight an apparent anisotropy of velocity change in single-station cross-components correlation, with larger amplitudes when correlating vertical and tangential components than using vertical and radial components with respect to the crater. The Mw = 8.1 Iquique earthquake on 1 April 2014 produced also a marked co-seismic velocity drop detected in a high frequency range(3–5 Hz) in both single-station cross-components correlation and cross-correlations. We locate in the horizontal plane and in depth the velocity perturbation and the structural change related with decorrelation. During the main phase of eruptive activity, the velocity decrease at low frequency (0.1–1 Hz) appears to affect the whole edifice mainly at depth of about 1 to 3 km below the surface. The structural perturbation is more concentrated on the south flank of the volcano, a zone that corresponds to an ancient collapse. We suggest that the observed velocity variations are due to the dilatation of the edifice and to microfracturation induced by magma pressurization. The structural change may be locally enhanced by a possible zone of material weakness in the southern sector. The co-seismic velocity perturbation is located mostly in the southeast flank, at depth smaller than 0.5 to 1 km, and may be related to the presence of the hydrothermal system of the volcano. • Noise correlation functions are calculated both on pairs of stations and on single stations. • Velocity decrease and waveform decorrelation are detected 3 weeks before eruption. • Velocity variations are larger when correlating tangential component than radial. • At higher frequency sharp velocity drop is induced by the M W = 8.1 Iquique earthquake. • Velocity and structural perturbations are located in the edifice at 1–3 km depth below crater. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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41. Geochemical signals related to the 2011–2012 El Hierro submarine eruption.
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Torres-González, Pedro, Moure-García, David, Luengo-Oroz, Natividad, Villasante-Marcos, Víctor, Iribarren, Ilazkiñe, Blanco, M. José, Soler, Vicente, Jiménez-Abizanda, Ana, and García-Fraga, José
- Subjects
- *
VOLCANIC eruptions , *SOIL air , *SOIL temperature , *RADON , *ATMOSPHERIC temperature , *CARBON dioxide - Abstract
On 10 October 2011, a submarine volcanic eruption began 2 km south of the island of El Hierro (Canary Islands, Spain). It was the first eruption after 40 years of quiescence in the Canarian archipelago. Since mid-July 2011, a multiparametric network has been deployed by the Instituto Geográfico Nacional (hereinafter IGN) to monitor volcanic processes. The data recorded by five stations, measuring the air and soil temperature, CO 2 and radon concentration in the air inside four galleries and one well, are the focus of the present paper. Two important anomalies were found that improve comprehension of the volcanic process. First, a clear increase in CO 2 concentration in one gallery (from 825 ± 19 to 2305 ± 35 ppm) which seems to be mainly controlled by ground deformation measured during the unrest period preceding the eruption. Second, a relationship between radon concentration in air in a well located in the northern side of the island with seismic energy release (several peaks with up to 115% increase), and ground deformation (50% growth in background level), also before the eruption onset. Lastly, changes in radon concentration during eruptive period seem to be modulated by seismic activity (increases up to 233%), which in turn is likely related to variations in magma rheology. • CO2 concentration in air in one gallery controlled by ground deformation during unrest period. • Sharp increases in radon concentration in one well related with changes in ground deformation rate before the eruption. • Variations in carbon dioxide concentration in one gallery linked with magma degassing in the eruption period • Changes in radon concentration in one well during eruptive process [ABSTRACT FROM AUTHOR]
- Published
- 2019
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42. Monitoring active fumaroles through time-lapse electrical resistivity tomograms: an application to the Pisciarelli fumarolic field (Campi Flegrei, Italy).
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Di Giuseppe, M.G. and Troiano, A.
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- *
ELECTRICAL resistivity , *VOLCANIC gases , *TIME series analysis , *DATA integration , *VOLCANOES , *SUBSOILS , *PHENOMENOLOGICAL theory (Physics) - Abstract
Abstract Volcanoes are usually monitored through observations of many physical and chemical phenomena. In the most dangerous cases, as the one of the Campi Flegrei caldera (Italy), great amount of data are collected, both in discrete or continuously, and regularly stored. However, how to transform such mass of data in a deeper understanding of the volcano dynamics is still an open question. Dissimilar information are in fact always hard to compare, but just integrating all the available knowledge hazardous events could be prevented in a reliable way. Fluids, as water and gasses mobilized in the subsoil by the heat induced by deep magmatic sources, are widely recognized as the first engine of similar occurrences and the volcanic gas emissions represent, together with the seismic activity, one of the most considered precursors. At the same time, the electrical geophysical methods are the most applied in order to detect and characterize the fluid patterns in the subsoil. So, the integration of geoelectrical and geochemical observations should represent one of the most pursued approach in volcanoes monitoring. On the contrary, standard way to compare such data has been not yet codified. The ERT tomograms capability to individuate that parts of the subsoil where gasses cumulate is well understood in literature. However, we look for indications about its proficiency in associating the electrical resistivity changes relative to these zones, once compared to the geochemical time series, to deep related contributes, distinguishing them from the seasonal ones. The electrical signature of the fluid patterns, reconstructed through a time-lapse ERT approach, could be of relevance to better characterize the volcanic phenomena and their origins. In this paper a first test of ERT and geochemical time series integration was performed to enhance the understanding of the Pisciarelli fumarolic field evolution, now the most active area in the whole Campi Flegrei caldera. Highlights • Time lapse ERT surveys were performed in the Pisciarelli site. • ERT and superficial data integration was performed to study the site. • Mutual relationship between the parameters and their interdependence is analysed. • Seasonal anomalies and features linked to volcanic contributions are marked. • A conceptual model of the fumarolized area is presented. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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43. Structural model and slip-dilation tendency analysis at the Copahue geothermal system: Inferences on the reservoir geometry.
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Barcelona, Hernan, Yagupsky, Daniel, Vigide, Nicolas, and Senger, Martin
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- *
GEOTHERMAL ecology , *GEOTHERMAL resources , *STRUCTURAL models , *GEOTHERMAL engineering , *RESERVOIRS , *GRABENS (Geology) , *FLUID flow - Abstract
Abstract The Copahue volcano host one of the most attractive geothermal resources of Argentina. Several studies focused on both the volcanic activity and the related geothermal manifestations, including a feasibility report during the '90s. However, limited, unclear and usually contradictory structural interpretations are found in the literature, and the role of the main faults over the geothermal system remains thus unsolved. This paper provides the first structural characterization and role assessment of the faults over the fluid flow and the reservoir geometry. A 3D structural model has been constructed to achieve this goal, and a fault-plane striations survey has been carried out at Anfiteatro, Termas and Maquinitas hydrothermal zones. Using this dataset, a slip and dilation tendency analysis over the main structures have been performed. The 3D structural model indicates that the Copahue geothermal field is bounded by an N60°-trending fault set and constrained to the north by the Trolope fault and to the south by the Chancho-Co fault, both with WNW-ESE trend. The collected fault-plain striations data was inverted to obtain the paleostress tensor related to the formation of the Copahue village fault system (CVFS), the structure that controls the hydrothermal areas. The subvertical maximum principal stress axis obtained defines a well constrained tensional regime, with a subhorizontal NW-SE minimum principal stress, consistent in all the surveyed locations. Both the 3D model and the inverted paleostress tensor indicate that the geothermal field, and probably the entire northeastern slope of the volcano, is subjected to an extensional faulting regime. Our analysis shows that the N°60-trending fault set is critically stressed for dilation and probably behaves as an active hydrological fault system, whereas the N105° and N135° fault sets have intermediate and low dilation tendency, respectively. These tendencies might lead to a northeast-trend fluid path between the Chancho-co and the N135° faults and might define the extension of the steam cap. We propose a compartmentalized reservoir model made up by three fault segmented blocks. While a steam cap over a deeper reservoir controlled by the CVFS characterizes the central segment, a pressurized liquid-dominated reservoir could prevail to the west of Termas and the east of Maquinas hydrothermal zones. This model explains the differences between the fumaroles inside the CVFS (i.e., Termas to Maquinas fumaroles) and outside this structural system (i.e., Anfiteatro), is consistent with the steam cap identified by the exploration boreholes and is consistent with the 3D structural framework proposed. Also, the model suggests that the collapse of the eastern slope of the Chancho-co hill might constitute the initial state of the current configuration of the geothermal system. Additional studies are needed to verify the proposed reservoir model before defining deep exploration targets, including magnetotellurics, discrete fracture network analysis, and preliminary thermodynamical models. Highlights • Geothermal field subjected to extensional stress regime(NW-SE Sh min) • N60°, N105°, and N135°-trending faults have respectively high, medium and low dilation tendency • Compartmentalized reservoir explains isotopic differences between fumaroles • Steam cap is related to the Copahue village extensional fault system [ABSTRACT FROM AUTHOR]
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- 2019
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44. Constraining age and volume of lava flow invasions of the Alcantara valley, Etna volcano (Italy). New insights from paleomagnetic dating and 3D magnetic modeling.
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Branca, Stefano, D'Ajello Caracciolo, Francesca, Malaguti, Arianna Beatrice, and Speranza, Fabio
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LAVA flows , *VOLCANIC eruptions , *VOLCANOES , *VOLCANIC fields , *VALLEYS , *WAR , *LAVA - Abstract
The Alcantara River marks the northern border of Etna volcano, and along its NE sector, it forms a narrow NW-SE elongated valley that is carved in the Mts. Peloritani sedimentary sequences. The valley has been invaded by several lava flows during the growth of the main bulk of the stratovolcano edifice in the past 60 ky (Ellittico and Mongibello volcanoes). In this paper, we have constrained the age of the main lava flows forming the valley floor and reconstructed the length and volume of the main lava flow that impacted this area through a multidisciplinary approach integrating stratigraphic and aeromagnetic data analysis together with new paleomagnetic and 14C dating. The new age determinations showed that the evolution of the present-day geological and hydrographic setting of the valley was mainly conditioned by a few flank eruptions that occurred in the lower N flank of Etna during the activity of the Mongibello volcano. In particular, between 13.9 and 9.7 ka BP the valley floor was filled by the so-called Alcantara lava flow for its entire length up to the river mouth, reaching a maximum length of about 24 km. Later, two other flank eruptions – producing the so-called Mt. Dolce and Solicchiata lava flows – occurred at 9.1–7.2 and 7.3–7.2 ka BP (respectively), covering the eruptive fissure and the proximal portion of the Alcantara lava field and generated the most recent northward shift of the riverbed. Finally, 3D magnetic modeling allowed us to calculate the total on- and off-shore volume of the Alcantara lava flow as 1 km3, a value comparable to those of the long-lasting historical eruptions of Etna. Conversely, the 24 km length reached by this lava flow is anomalously high when compared to lava flows of the past 15 ky, likely because its emplacement occurred within the valley floor, preventing any possibility of lateral expansion. • The paleomagnetic and 14C datings allow constraining the timing of lava flow invasions of the Alcantara valley • the main lava flow that filled the entire valley was emplaced between 9.7 and 13.9 ka BP • The lava volume of 1 km3 of the Alcantara flow is comparable to the highest lava volumes of the historical Etna's eruptions • The maximum length of the lava flow is about 24 km [ABSTRACT FROM AUTHOR]
- Published
- 2019
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45. Mini-columns and ghost columns in Columbia River lava.
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Moore, James G.
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LAVA , *LAVA flows , *STEAM flow , *RIVERS - Abstract
The master joints bounding the columns that make up the basal colonnade of large lava flows of the Columbia Plateau are, in places, flanked by sub-horizontal mini-columns that have grown normal to the master joints. The secondary mini-columns grow into the main columns and are clearly younger than them. They are small adjacent to the master joint, but merge together and thicken away from the fracture toward the master column interior. Commonly the mini-columns are one-half meter in length and 2–12 cm in diameter. Where the horizontal mini-columns grow longer they intersect toward the middle of the master joints. This plexus of joints changes the aspect of the original master columns making them almost unrecognizable producing ghost columns. The basalt flow may acquire an entablature-like appearance where the ghost column outlines disappear due to extensive secondary fracturing. At the time that the hot flow center had cooled sufficiently below the brittle-plastic transformation, the primary vertical basal colonnade joints growing up from the bottom connected with those in the upper colonnade growing down. This allowed steam trapped beneath the flow to be released to the surface and ushered in a change from a conduction-cooling regime to a convection-cooling regime. The steam beneath the flow was formed and sustained by heat from the lava that boiled the groundwater in the underlying substrate. Large volumes of the rising steam was on average much cooler than the hot fractures in the flow interior through which it passed, causing contraction of the master column walls to produce the secondary horizontal mini-columns. The presence of mini-columns indicates emplacement of lava over moist ground and are absent where the lavas advanced across arid areas or flowed over recently-erupted lava. The extreme shattering that forms ghost columns by late stage convective cooling can produce a flow layer of considerable thickness, a layer that can later serve as an aquifer with high porosity and permeability. • This paper describes newly recognized types of columnar joints from the Miocene Columbia River Basalt Group in Washington and Oregon. • Horizontal mini-columns form as the walls of previously formed master basal columns are cooled by the escape of steam trapped beneath the lava flow. • Where numerous mini-columns intersect one another the original master column is almost unrecognizable as ghost columns are produced. • Recognition of these column types opens the door for new interpretations and models of columnar joint formation. [ABSTRACT FROM AUTHOR]
- Published
- 2019
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46. Magmatic evolution and textural development of the 1739 CE Pietre Cotte lava flow, Vulcano, Italy.
- Author
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Bullock, Liam A., Gertisser, Ralf, O'Driscoll, Brian, and Harland, Sophie
- Subjects
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MAGMAS , *RHYOLITE , *TRACHYTE , *SPHERULITES (Petrology) - Abstract
Abstract Textural evidence from occurrences of mingled magmas in lava flows often yields insights into chemical and thermal disequilibrium between multiple magma batches at depth. An understanding of these interactions is key as they can occur on short timescales and may act as eruption triggers, particularly important in very active volcanic settings. This paper focuses on the Pietre Cotte lava flow (Vulcano, Aeolian Islands, Italy), a short (<1 km in length), texturally-heterogeneous rhyolitic extrusion on the northern slope of the active Fossa Cone. The occurrence of (i) multiple magma compositions, (ii) distinct magmatic cumulates (as glomerocrysts) and (iii) mineral resorption textures within glomerocrysts and isolated feldspar phenocrysts in the Pietre Cotte lava flow highlight a complex pre-eruptive magmatic history, including crystal mush remobilisation. Petrographic observations and mineral, bulk rock and glass geochemistry suggest that multiple mingling events occurred during the evolution of the Pietre Cotte magmatic system, evidenced by the recognition of the following components: (1) a remobilised predominantly mafic crystal mush, evident as macrocrysts (crystals >500 μm), which form glomerocrysts within enclaves, (2) a microlitic (<100 μm) trachytic enclave groundmass with microcrysts (100–500 μm), and (3) a rhyolitic glass, which hosts both the enclaves and the glomerocrysts. The macrocrystic mafic assemblage includes clinopyroxene (En 38-47 Wo 45–50 ; Mg# 0.72–0.89), olivine (Fo 49–66) and magnetite (Usp 7–26), with plagioclase (An 40–63 Ab 5–50) and rare alkali feldspar (Or 41–57) also present. Enclaves are comprised of a groundmass of plagioclase (An 43–47) and alkali feldspar (Or 33–57) microlites, with clinopyroxene microcrysts (En 39-42 Wo 47–51 ; Mg# 0.75–0.81) and trachyte groundmass glass. The rhyolitic host is characterised by glass, spherulites, microlites and enclave-derived macrocrysts. Compositionally and texturally distinct magmas are attributed to storage and interactions of distinct magma batches and their cumulates at various temperatures and depths beneath the Fossa Cone. Compositions vary from basaltic-shoshonitic, through latitic-trachytic and rhyolitic magmas. The macrocrystic glomerocryst assemblage shows resorbed, chemically-zoned and cumulate textures; the glomerocrysts are attributed to a shoshonitic parent and remobilisation from a crystal mush. Macrocrysts formed at a pressure of 825 ± 80 MPa and temperatures of 789–1117 °C at around the Moho (~23–28 km). Pressure and temperature calculations of the shoshonitic mineral assemblage give average crystallisation conditions of 710 ± 80 MPa (above the Moho) and 1128 ± 25 °C, respectively. The trachytic magma crystallised at ~640 ± 75 MPa and 1000–1130 °C. The average liquidus of the rhyolitic magma has been calculated at 970 ± 7 °C, at depths of <5 km (<60 MPa). New textural observations and intensive variable calculations permit the development of a new pressure and temperature-constrained model of the magmatic evolution of the Pietre Cotte system prior to eruption, with useful insights into the interactions of different magmatic components prior to and during the rapid onset of eruptions linked to magma mingling/mixing. Highlights • Disequilibrium textures in the Pietre Cotte lava flow signify a complex evolution. • Petrography and geochemistry highlight several magmatic mingling events. • Crystal mush, trachyte and rhyolite magmas interacted at various crustal depths. • Shallow magmatic interactions may trigger eruptions following migration from depth. [ABSTRACT FROM AUTHOR]
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- 2019
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47. Modelling the instability phenomena on the NW flank of Stromboli Volcano (Italy) due to lateral dyke intrusion.
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Verrucci, Luca, Tommasi, Paolo, Boldini, Daniela, Graziani, Alessandro, and Rotonda, Tatiana
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MAGMAS , *VOLCANIC eruptions , *STRESS-strain curves , *LIQUEFACTION (Physics) , *SLOPES (Physical geography) - Abstract
Abstract The aim of the paper is to provide quantitative elements on the mechanisms that controlled the slope instabilities occurred after two major recent eruptions at Stromboli volcano (i.e. 2002–2003 and 2007). After a brief description of the geological setting and of the largest well documented instability phenomena on volcano flanks, the main objective is pursued using three-dimensional stress-strain analyses for modelling the effects of the magma intrusion on the stability of the volcano flank. Modelling is based on the results of an extensive geotechnical characterization of the volcaniclastic and lava materials. The numerical analyses investigate the influence of different paths and geometry of magma intrusion as well as the spatial variation of mechanical properties. As a result, favourable conditions for specific failure modes are identified. The stress-strain analyses show that magma intrusion can cause both a local failure of a wedge immediately downslope from the dyke or deep-seated movement involving large part of the slope; these two mechanisms were consistent with the deformative patterns observed during the 2007 and 2002–2003 eruptions, respectively. The magma thrust induces shear strains up to levels associated to appreciable grain crushing even below the sea level, where flow liquefaction can be invoked to explain the occurrence of past submarine slides. The submarine landslide is analysed by a combined finite element – limit equilibrium approach that demonstrates that instability conditions can develop if the loading exerted by the upper portion of the slope is sufficiently fast to produce undrained conditions. The analyses also support the hypothesis that at the 2002 subaerial failure occurred, due to combined effects of a magma mild thrust and the removal of the toe support caused by the preceding submarine slide. Highlights • Volcanological evidences were useful for modelling the slope movements of Stromboli. • Subvertical dyke intrusion affects only local stability of the dry subaerial slope. • Larger instabilities can be triggered only by dyke intrusion with relevant horizontal component. • Static liquefaction due to grain crushing can explain the submarine slide. • Submarine sliding can propagate backwards and influence the subaerial sector. [ABSTRACT FROM AUTHOR]
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- 2019
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48. SBAS interferometric analysis for volcanic eruption of Hawaii island.
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Babu, Arun and Kumar, Shashi
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VOLCANIC eruptions , *EARTHQUAKES , *TIME series analysis , *SEISMOMETERS - Abstract
Abstract The Kilauea volcano on the Hawaii island started erupting on 3rd May 2018 after an earthquake of magnitude 5.0. The initial volcano eruption and the subsequent earthquakes resulted in the opening of new volcanic fissures, continuous lava flow at the lower east rift zone and the collapse of the summit caldera floor. All these activities continued until the 1st week of August 2018. The Small Baseline Subset (SBAS) technique is an advanced form of Differential Interferometry (DInSAR) which is capable of monitoring surface deformations with millimetre level accuracy. SBAS technique was utilised here for estimating the surface deformation on Hawaii island due to the volcanic episode. InSAR coherence technique was also utilised in this study for localised analysis at the summit and at the lower east rift zone to detect the time series deformation information and lava flow patterns. 14 interferometric datasets acquired by the ESA's Sentinel-1 C-band satellite from April 2018 to September 2018 were used in this study. The data acquired by the seismometers installed at Kilauea by Hawaii Volcano Observatory, the SWIR band of Sentinel-2 and the thermal band of Landsat-8 were used to correlate and verify the results obtained through the SBAS and InSAR coherence analysis. The combined interpretation of results obtained from all the sources gave insights about the underground magma conduit system, surface deformations, lava flow channels and the correlation between the magmatic and seismic activity happened there which are discussed in detail in this paper. Highlights • Detected subsidence at the Kilauea summit and Puu Oo crater due to magma withdrawal • Increased seismic activity at summit due to Caldera floor collapse • Open channel lava flow from fissures at Leilani Estates • Lava delta formation due to ocean entry of lava flowing through open channel • Sub-terrain magma conduit from summit reservoir to Leilani Estates [ABSTRACT FROM AUTHOR]
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- 2019
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49. Imaging the 2013 explosive crater excavation and new dome formation at Volcán de Colima with TerraSAR-X, time-lapse cameras and modelling.
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Walter, Thomas R., Harnett, Claire E., Varley, Nick, Bracamontes, Dulce Vargas, Salzer, Jacqueline, Zorn, Edgar U., Bretón, Mauricio, Arámbula, Raúl, and Thomas, Mark E.
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LAVA domes , *REMOTE sensing , *IMPACT craters , *VOLCANISM , *AERIAL photogrammetry - Abstract
Abstract The summit region of steep volcanoes hosting lava domes often displays rapid geomorphologic and structural changes, which are important for monitoring the source region of hazards. Explosive crater excavation is often followed by new lava-dome growth, which is one of the most dynamic morphometric changes that may occur at volcanoes. However, details of these crater formations, and the ensuing new dome growth remain poorly studied. A common problem is the lack of observational data due to hazardous field access and the limited resolution of satellite remote sensing techniques. This paper describes the destructive-constructive crater activity at Volcán de Colima, Mexico, which occurred between January and March 2013. The crater geometry and early dome formation were observed through a combination of high-resolution TerraSAR-X spotmode satellite radar images and permanently installed monitoring cameras. This combined time-lapse imagery was used to identify ring-shaped gas emissions prior to the explosion and to distinguish between the sequential explosion and crater excavation stages, which were followed by dome growth. By means of particle image velocimetry, the digital flow field is computed from consecutive camera images, showing that vertical dome growth is dominant at the beginning. The upward growth is found to grade into spreading and a lateral growth domain. After approximately two months of gradually filling the excavated craters with new magma, the dome overflows the western margin of the crater and develops into a flow that produces block and ash flow hazards. We discuss and compare the observations to discrete element models, allowing us to mimic the vertical and lateral growth history of the dome and to estimate the maximum strength of the bulk rock mass. Moreover, our results allow a discussion on the controls of a critical dome height that may be reached prior to its gravitational spreading. Graphical abstract Unlabelled Image Highlights • Crater formation and lava-dome growth monitored at Volcán de Colima, Mexico • Spotlight satellite radar and time-lapse camera data show morphologic changes at high resolution • Ring-shaped gas emissions prior to Vulcanian explosions, and crater formation at the volcano summit • Data suggests that dome growth is first mainly vertical, reaching a critical dome height followed by lateral spreading of the dome • Numerical models allow to simulate the growing dome and to estimate the maximum strength of the rock mass [ABSTRACT FROM AUTHOR]
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- 2019
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50. UAVs for volcano monitoring: A new approach applied on an active lava flow on Mt. Etna (Italy), during the 27 February–02 March 2017 eruption.
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De Beni, Emanuela, Cantarero, Massimo, and Messina, Alfio
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VOLCANOES , *DRONE aircraft , *LAVA , *LANDFORMS , *AUTONOMOUS vehicles - Abstract
Abstract Mt. Etna (Italy) with 55 effusive events in the last six years is one of the most active volcanoes in the world, with a million people living on its flank and thousands of tourists who visit it every summer. For this reason, the lava flow monitoring for risk mitigation and Civil Protection purposes is one of the fundamental tasks of the Cartographic Laboratory of the Istituto Nazionale di Geofisica e Vulcanologia, Osservatorio Etneo. This activity was traditionally performed using data collected from the field (with terrestrial GPS surveys) and from helicopter taking visible and thermal images. During the 27 February–02 March 2017 eruption the FlyEye Team, applied Unmanned Aerial Vehicles to monitor the active lava flow. Two high-resolution UAV surveys were performed on the lava flow field on the south flank of Mt. Etna, between 3050 and 2600 m a.s.l., obtaining almost 1170 images. Structure-from-Motion techniques were applied to create orthophotos and Digital Elevation Models (DEM) of the lava flow field and surroundings. The obtained DEM has a resolution of 14.2, and 20.7 cm/px for the main lava flow and the west branch, respectively. On the wall, the 96% of the lava flow field was mapped using aerial images by UAV covering an area of 0.3 × 106 m2. Lava flow volume was calculated with the topographic approach: difference between post- and pre-eruption surface, DEM 2017 and DEM 2014, respectively. The impossibility of spreading the GCPs homogenously distorted the resulting DEM; for this reason, it was necessary to align the lava flow point clouds, obtained from the photogrammetry software, to the basal 2014 DEM. Subtracting the two DEMs a lava flow thickness grid resulted leading to a total volume of 1.4 × 106 m3 and an error estimation of about 20%. Finally, dividing the total volume for the effusion duration (63 h) a mean output rate of 6.2 m3/s resulted. The calculated volcanological parameters have the same order of magnitude of the previous activity of Mt. Etna, between 2011 and 2016. This research demonstrates that UAV photogrammetry was successfully exploited during an eruptive crisis, allowing a first fast processing, to obtain an orthophoto of the lava flow field, useful for "decision makers" and a further slower processing for the realization of a high-resolution DEM. The latter makes it possible to update the topography, another important argument for Civil Protection purpose. This paper describes a methodology that could be applied during other natural events in extreme environmental conditions. Highlights • UAV as a support in volcanological monitoring: maps and volume estimation. • Unconventional solutions in UAV survey during an eruptive crisis. • The usage of a Natural Neighbor interpolated basal surface when a pre-eruption surface and/or GCPs lack. • A point cloud manipulation software is necessary for clouds alignment. • Etna 27 February - 2 March 2017 eruption volume calculated with topographic approach is 1.4 × 106 m3. [ABSTRACT FROM AUTHOR]
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- 2019
- Full Text
- View/download PDF
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