Your search keyword '"Sebastian Watt"' showing total 9 results

1. Long-term volcano evolution controlled by lateral collapse at Antuco volcano, southern Andes, Chile

Author

Jorge E. Romero, Margherita Polacci, Fabio Arzilli, C. Ian Schipper, Giuseppe La Spina, Mike Burton, Miguel A. Parada, Juan Norambuena, Alicia Guevara, Sebastian Watt, Hugo Moreno, Luis Franco, and Jonathan Fellowes

Subjects

Geology, QE1-996.5, Environmental sciences, GE1-350

Abstract

Abstract Beyond the catastrophic environmental effects of large (>1 km3) volcanic landslides, their impact on underlying magmatic systems remains unclear. Chemical variations in post-collapse volcanic products, alongside dramatic eruptive behaviour transitions reported from several volcanoes, imply that surface unloading directly influences subsurface magmatic processes. By combining petrologic data with magma ascent models, we track the post-collapse (

Published

2023

2. The Contributions of Marine Sediment Cores to Volcanic Hazard Assessments: Present Examples and Future Perspectives

Author

Chris Satow, Sebastian Watt, Mike Cassidy, David Pyle, and Yuqiao Natalie Deng

Subjects

volcanic hazard, marine sediment core, tephra, volcanic ash, Geology, QE1-996.5

Abstract

The rigorous assessment of volcanic hazards relies on setting contemporary monitoring observations within an accurate, longer-term geological context. Revealing that geological context requires the detailed fieldwork, mapping and laboratory analysis of the erupted materials. However, many of the world’s most dangerous volcanic systems are located on or near coasts (e.g., the Phlegraean Fields and Vesuvius in Italy), islands (e.g., the volcanic archipelagos of the Pacific, south-east Asia, and Eastern Caribbean), or underwater (e.g., the recently erupting Hunga Tonga–Hunga Ha’apai volcano), meaning that much of their erupted material is deposited on the sea bed. The only way to sample this material directly is with seafloor sediment cores. This perspectives paper outlines how marine sediment cores are a vital yet underused resource for assessing volcanic hazards by: (1) outlining the spatio-temporal scope of the marine volcanic record and its main deposit types, (2) providing existing examples where marine sediments have contributed to volcanic hazard assessments; (3) highlighting the Sunda Arc, Indonesia as an example location where marine sediment cores are yet to contribute to hazard assessments, and (4) proposing that marine sediment cores can contribute to our understanding of very large eruptions that have a global impact. Overall, this perspectives paper aims to promote the utility of marine sediment cores in future volcanic hazard assessments, while also providing some basic information to assist researchers who are considering integrating marine sediment cores into their volcanological research.

Published

2023

3. Volcanic Lateral Collapse Processes in Mafic Arc Edifices: A Review of Their Driving Processes, Types and Consequences

Author

Jorge E. Romero, Margherita Polacci, Sebastian Watt, Shigeru Kitamura, Daniel Tormey, Gerd Sielfeld, Fabio Arzilli, Giuseppe La Spina, Luis Franco, Mike Burton, and Edmundo Polanco

Subjects

edifice instability, landslide, unloading, decompression, volcanic geomorphology, debris avalanche, Science

Abstract

Volcanic cones are frequently near their gravitational stability limit, which can lead to lateral collapse of the edifice, causing extensive environmental impact, property damage, and loss of life. Here, we examine lateral collapses in mafic arc volcanoes, which are relatively structurally simple edifices dominated by a narrow compositional range from basalts to basaltic andesites. This still encompasses a broad range of volcano dimensions, but the magma types erupted in these systems represent the most abundant type of volcanism on Earth and rocky planets. Their often high magma output rates can result in rapid construction of gravitationally unstable edifices susceptible both to small landslides but also to much larger-scale catastrophic lateral collapses. Although recent studies of basaltic shield volcanoes provide insights on the largest subaerial lateral collapses on Earth, the occurrence of lateral collapses in mafic arc volcanoes lacks a systematic description, and the features that make such structures susceptible to failure has not been treated in depth. In this review, we address whether distinct characteristics lead to the failure of mafic arc volcanoes, or whether their propensity to collapse is no different to failures in volcanoes dominated by intermediate (i.e., andesitic-dacitic) or silicic (i.e., rhyolitic) compositions? We provide a general overview on the stability of mafic arc edifices, their potential for lateral collapse, and the overall impact of large-scale sector collapse processes on the development of mafic magmatic systems, eruptive style and the surrounding landscape. Both historical accounts and geological evidence provide convincing proofs of recurrent (and even repetitive) large-scale (>0.5 km3) lateral failure of mafic arc volcanoes. The main factors contributing to edifice instability in these volcanoes are: (1) frequent sheet-like intrusions accompanied by intense deformation and seismicity; (2) shallow hydrothermal systems weakening basaltic rocks and reducing their overall strength; (3) large edifices with slopes near the critical angle; (4) distribution along fault systems, especially in transtensional settings, and; (5) susceptibility to other external forces such as climate change. These factors are not exclusive of mafic volcanoes, but probably enhanced by the rapid building of such edifices.

Published

2021

4. Mapping Recent Shoreline Changes Spanning the Lateral Collapse of Anak Krakatau Volcano, Indonesia

Author

Alessandro Novellino, Samantha L. Engwell, Stephen Grebby, Simon Day, Michael Cassidy, Amber Madden-Nadeau, Sebastian Watt, David Pyle, Mirzam Abdurrachman, Muhammad Edo Marshal Nurshal, David R. Tappin, Idham Andri Kurniawan, and James Hunt

Subjects

sentinel-2, shoreline, google earth engine, cloud computing, explosive volcanism, tsunami hazards, anak krakatau, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

We use satellite imagery to investigate the shoreline changes associated with volcanic activity in 2018−2019 at Anak Krakatau, Indonesia, spanning a major lateral collapse and period of regrowth through explosive activity. The shoreline changes have been analyzed and validated through the adaptation of an existing methodology based on Sentinel-2 multispectral imagery and developed on Google Earth Engine. This work tests the results of this method in a highly dynamic volcanic environment and validates them with manually digitized shorelines. The analysis shows that the size of the Anak Krakatau Island increased from 2.84 km2 to 3.19 km2 during 15 May 2018−1 November 2019 despite the loss of area in the 22 December 2018 lateral collapse. The lateral collapse reduced the island area to ~1.5 km2 but this was followed by a rapid increase in area in the first two months of 2019, reaching up to 3.27 km2. This was followed by a period of little change as volcanic activity declined and then by a net decrease from May 2019 to 1 November 2019 that resulted from erosion on the SW side of the island. This history of post-collapse eruptive regrowth and coastal erosion derived from the shoreline changes illuminates the potential for satellite-based automated shoreline mapping to provide databases for monitoring remote island volcanoes.

Published

2020

5. Large Submarine Landslides on Continental Slopes: Geohazards, Methane Release, and Climate Change

Author

Peter J. Talling, Michael Clare, Morelia Urlaub, Ed Pope, James E. Hunt, and Sebastian Watt

Subjects

submarine landslides, submarine hazards, methane emissions, Storegga slide, earthquake triggers, Oceanography, GC1-1581

Abstract

Submarine landslides on open continental slopes can be prodigious in scale. They are an important process for global sediment fluxes, and can generate very damaging tsunamis. Submarine landslides are far harder to monitor directly than terrestrial landslides, and much greater uncertainty surrounds their preconditioning factors and triggers. Submarine slope failure often occurs on remarkably low (< 2°) gradients that are almost always stable on land, indicating that particularly high excess pore pressures must be involved. Earthquakes trigger some large submarine landslides, but not all major earthquakes cause widespread slope failure. The headwalls of many large submarine landslides appear to be located in water depths that are too deep for triggering by gas hydrate dissociation. The available evidence indicates that landslide occurrence is either weakly (or not) linked to changes in sea level or atmospheric methane abundance, or the available dates for open continental slope landslides are too imprecise to tell. Similarly, available evidence does not strongly support a view that landslides play an important role in methane emissions that cause climatic change. However, the largest and best-dated open continental slope landslide (the Storegga Slide) coincides with a major cooling event 8,200 years ago. This association suggests that caution may be needed when stating that there is no link between large open slope landslides and climate change.

Published

2014

6. Flank collapse, sediment failure and flow-transition: the multi-stage deposition of a volcanic sector collapse offshore Montserrat, Lesser Antilles

Author

Michel Kühn, Christian Berndt, Sebastian Krastel, Jens Karstens, Sebastian Watt, Steffen Kutterolf, Katrin Huhn, and Tim Freudenthal

Abstract

Volcanic sector collapses generated some of the most voluminous mass transport deposits on Earth and triggered devastating tsunamis with numerous casualties. The associated sector collapse deposits occur around many volcanic islands all over the world. The shelf around the volcanic island of Montserrat (Lesser Antilles) and the adjacent Montserrat-Bouillante-Graben host more than ten surficial or buried landslide deposits with most of them classified as volcanic debris avalanche deposits by previous studies. The most intensively studied deposit (Deposit 2) is associated with a landslide that occurred at ~ 130 ka and comprises a volume of 10 km³, including remnants of the volcanic flank and secondarily mobilized seafloor sediments. Here, we present new 2D and 3D seismic data as well as MeBo drill core data from Deposit 2 that reveal multi-phase deposition including an initial blocky volcanic debris avalanche followed by secondary seafloor failure and a late- erosive event. Late-stage erosion is evidenced by a channel-like incision on the hummocky surface of Deposit 2 about 15 km from the source region. Erosional incisions into the top of sector collapse deposit have also been reported from Ritter Island, Papua New Guinea – the only other volcanic landslide deposit that was studied at similarly high resolution. This may imply that late stage erosive turbidites are a common process during volcanic sector collapse. This requires geological and oceanographic processes that can create high flow velocities close to the source of the collapse area leading to a late down-slope acceleration of sediments that were suspended in the water column.

Published

2023

7. Volcanic Island Sector Collapse: Reconstruction of volcanic activity and implications for subsequent mass movements from marine records drilled with MeBo70 offshore Montserrat (Lesser Antilles)

Author

Kristina Sass, Steffen Kutterolf, Tim Freudenthal, Sebastian Watt, Christian Berndt, Sebastian Krastel, and Katrin Huhn

Abstract

Volcanic island sector collapses produce some of the volumetrically largest mass movements on Earth. They may trigger devastating tsunamis that pose hazards to coastal communities and endanger seafloor installations. However, very little is currently known about the interplay between volcanic activity and subsequent mass wasting (volume, source location, and trans­port dis­tance) as well as their specific em­place­ment pro­cesses (tim­ing, kin­emat­ics, and dy­nam­ics). Moreover, these are key information to de­vel­op­ a re­li­able tsunami haz­ard as­sess­ment for sec­tor col­lapses.The volcanic island of Montserrat in the Lesser Antilles is an ideal target to study the timing, frequency, and kinematics of sec­tor col­lapses as well as subsequent mass wasting. In 2019, Meteor expedition M154 investigated the major landslide complex – Deposit 2, located in the southeast offshore sector of Montserrat and provided an outstanding geophysical (M154-1) and sedimentological dataset. Here, the second leg, M154-2, focused on sediment sampling. Within and in the vicinity of Deposit 2, drill cores were taken with the MeBo70 drill rig from up to 63 mbsf. Ad­di­tion­ally, 21 sup­ple­ment­ing grav­ity cores were taken in the vi­cin­ity of Me­Bo70 drill sites and along systematic transects across the slid masses. Sedimentological, geophysical, geotechnical as well as geochemical analyses of these sediment cores enable a unique opportunity to gain new insights into timing of mass wasting events and complement information on the volcanic island evolution.Based on these sediment cores, this pro­ject aims at con­trib­ut­ing to the gen­eral com­pre­hen­sion of vol­canic is­land sec­tor col­lapses, par­tic­u­larly the in­ter­re­la­tion­ship of vol­canic pro­cesses and as­so­ci­ated mass move­ments by establishing an event chronostratigraphy for the marine sediment records off Montserrat volcanic island.Samples from four MeBo70 drill sites at the undisturbed slope, the central and distal part of Deposit 2, and south of Montserrat were analyzed for their componentry and composition. The sediments predominantly comprise mud-rich facies interbedded with fine to coarse-grained, better-sorted sands. The sandy intervals sometimes show multiple units defined by normally-graded beds or sharp color changes with variable proportions of volcanic and biogenic clasts. In a small number, coarse volcanic sands to volcaniclastic gravels were encountered. Tuffaceous deposits are less frequent. Petrographic analyses of selected samples by polarized light microscopy enable the investigation of clast inventories to differentiate between sediment units. Geochemical fingerprinting of major elements of volcanic glasses by electron microprobe elucidates this differentiation. The geochemical analyses further show a mainly basaltic to rhyolitic volcanism in the range of Arc Tholeiitic and Calc-alkaline series. The analyzed samples represent different stages of volcanic island evolution with periods of increased volcanic activity and eruptions, flank collapses, submarine mass wasting events, and periods of relative inactivity. Moreover, trace element analyses by laser ablation inductively coupled plasma-mass spectrometry of selected potential primary volcanic layers enable the possibility to better distinguish between single eruptions and also to narrow down their source area(s) as well as that of the sedimentary material.

Published

2023

8. Downward-propagating eruption following vent unloading implies no direct magmatic trigger for the 2018 lateral collapse of Anak Krakatau

Author

Kyra Cutler, Sebastian Watt, Mike Cassidy, Amber Madden-Nadeau, Samantha Engwell, Mirzam Abdurrachman, Muhammad Nurshal, David Tappin, Steven Carey, Alessandro Novellino, Catherine Hayer, James Hunt, Simon Day, Stephan Grilli, Idham Kurniawan, and Nugraha Kartadinata

Abstract

The lateral collapse of Anak Krakatau volcano, Indonesia, in December 2018 highlighted the potentially devastating impacts of volcanic edifice instability. Nonetheless, the trigger for the Anak Krakatau collapse remains obscure. The volcano had been erupting for the previous six months, and although failure was followed by intense explosive activity, it is the period immediately prior to collapse that is potentially key in providing identifiable, pre-collapse warning signals. Here, we integrate physical, microtextural and geochemical characterisation of tephra deposits spanning the collapse period. We demonstrate that the first post-collapse eruptive phase (erupting juvenile clasts with a low microlite areal number density and relatively large microlites, reflecting a crystal-growth dominated regime) is best explained by instantaneous unloading of a relatively stagnant upper conduit. This was followed by the second post-collapse phase, on a timescale of hours, which tapped successively hotter and deeper magma batches, reflected in increasing plagioclase anorthite content and more mafic glass compositions, alongside higher calculated ascent velocities and decompression rates. The characteristics of the post-collapse products imply downward propagating destabilisation of the magma storage system as a response to collapse, rather than pre- collapse magma ascent triggering failure. Importantly, this suggests that the collapse was a consequence of longer-term processes linked to edifice growth and instability, and that no indicative changes in the magmatic system could have signalled the potential for incipient failure. Therefore, monitoring efforts may need to focus on integrating short- and long-term edifice growth and deformation patterns to identify increased susceptibility to lateral collapse. The post-collapse eruptive pattern also suggests a magma pressurisation regime that is highly sensitive to surface-driven perturbations, which led to elevated magma fluxes after the collapse and rapid edifice regrowth. Not only does rapid regrowth potentially obscure evidence of past collapses, but it also emphasises the finely balanced relationship between edifice loading and crustal magma storage.

Published

2022

9. Landslide and tsunami hazard at Yate volcano, Chile as an example of edifice destruction on strike-slip fault zones.

Author

Sebastian Watt, David Pyle, José Naranjo, and Tamsin Mather

Subjects

*LANDSLIDES, *TSUNAMIS, *STRIKE-slip faults (Geology), *VOLCANOES, *VOLCANOLOGY, *FAULT zones

Abstract

Abstract  The edifice of Yate volcano, a dissected stratocone in the Andean Southern Volcanic Zone, has experienced multiple summit collapses throughout postglacial time restricted to sectors NE and SW of the summit. The largest such historic event occurred on 19th February 1965 when ∼6.1–10 × 106 m3 of rock and ice detached from 2,000-m elevation to the SW of the summit and transformed into a debris flow. In the upper part of the flow path, velocities are estimated to have reached 40 m s−1. After travelling 7,500 m and descending 1,490 m, the flow entered an intermontane lake, Lago Cabrera. A wavemaker of estimated volume 9 ± 3 × 106 m3 generated a tsunami with an estimated amplitude of 25 m and a run-up of ∼60 m at the west end of the lake where a settlement disappeared with the loss of 27 lives. The landslide followed 15 days of unusually heavy summer rain, which may have caused failure by increasing pore water pressure in rock mechanically weathered through glacial action. The preferential collapse directions at Yate result from the volcano’s construction on the dextral strike-slip Liquiñe-Ofqui fault zone. Movement on the fault during the lifetime of the volcano is thought to have generated internal instabilities in the observed failure orientations, at ∼10° to the fault zone in the Riedel shear direction. This mechanically weakened rock may have led to preferentially orientated glacial valleys, generating a feedback mechanism with collapse followed by rapid glacial erosion, accelerating the rate of incision into the edifice through repeated landslides. Debris flows with magnitudes similar to the 1965 event are likely to recur at Yate, with repeat times of the order of 102 years. With a warming climate, increased glacial meltwater due to snowline retreat and increasing rain, at the expense of snow, may accelerate rates of edifice collapse, with implications for landslide hazard and risk at glaciated volcanoes, in particular those in strike-slip tectonic settings where orientated structural instabilities may exist. [ABSTRACT FROM AUTHOR]

Published

2009