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1. Forearc crustal faulting and estimated worst-case tsunami scenario in the upper plate of subduction zones. Case study of the Morne Piton Fault system (Lesser Antilles, Guadeloupe Archipelago)

Author

Philippon, Melody, Roger, Jean, Lebrun, Jean Frédéric, Thinon, Isabelle, Foix, Oceane, Mazzotti, Stéphane, Gutscher, Marc-andre, Montheil, Leny, Cornée, Jean-jacques, Philippon, Melody, Roger, Jean, Lebrun, Jean Frédéric, Thinon, Isabelle, Foix, Oceane, Mazzotti, Stéphane, Gutscher, Marc-andre, Montheil, Leny, and Cornée, Jean-jacques

Abstract

In this study, alternatively to the megathrust, we identify upper plate normal faults orthogonal to the trench as a possible tsunami source along the Lesser Antilles subduction zone. We study the Morne Piton Fault system, a trench-perpendicular upper crustal fault affecting the Lesser Antilles forearc at the latitude of Guadeloupe. By the means of seismic reflection, high resolution bathymetry, Remotely Operated Vehicle images and dating, we reassess the slip rate of the Morne Piton Fault at 0.2 mm.yr-1 since fault inception (i.e. 7 Ma), dividing by five previous estimations and thus increasing the earthquake time recurrence and lowering the associated hazard. We evidence a metric scarp with striae at the toe of the Morne Piton Fault system suggesting a recent fault rupture. We estimate a fault rupture area of ~ 450–675 km2 and then a magnitude range for the seismic event around Mw 6.5 ± 0.5. We present results from a multi-segment tsunami model representative for the worst-case scenario which gives an overview of what could happen in terms of tsunami generation if the whole identified Morne Piton Fault segments ruptured together. Our model illustrates the potential impact of local tsunamis on the surrounding coastal area as well as local bathymetric controls on tsunami propagation as (i) shallow water plateaus act as secondary sources and are responsible for a wrapping of the tsunami waves around the island of Marie-Galante, (ii) canyons are focusing and enhancing the wave height in front of the most touristic and populated town of the island, (iii) a resonance phenomenon is observed within Les Saintes archipelago showing that the waves’ frequency content is able to perturbate the sea-level during many hours after the seismic rupture.

Published
2024
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3. The Alpine Orogeny in the West and Southwest Iberia Margins

Author

Terrinha, Pedro, Ramos, Adrià, Neres, Marta, Valadares, Vasco, Duarte, João, Martínez-Loriente, Sara, Silva, Sónia, Mata, João, Kullberg, José Carlos, Casas-Sainz, Antonio, Matias, Luís, Fernández, Óscar, Muñoz, Josep Anton, Ribeiro, Carlos, Font, Eric, Neves, Conceição, Roque, Cristina, Rosas, Filipe, Pinheiro, Luís, Bartolomé, Rafael, Sallarès, Valentí, Magalhães, Vítor, Medialdea, Teresa, Somoza, Luis, Gràcia, Eulàlia, Hensen, Christian, Gutscher, Marc-André, Ribeiro, António, Zitellini, Nevio, Oberhänsli, Roland, Series Editor, de Wit, Maarten J., Series Editor, Roure, François M., Series Editor, Quesada, Cecilio, editor, and Oliveira, José Tomás, editor

Published
2019
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5. Limits of the seismogenic zone in the epicentral region of the 26 December 2004 great Sumatra-Andaman earthquake: Results from seismic refraction and wide-angle reflection surveys and thermal modeling

Author

Klingelhoefer, Frauke, Gutscher, Marc-André, Ladage, S., Dessa, J. -X., Graindorge, David, Franke, D., André, C., Permana, Haryadi, Yudistira, T., and Chauhan, Ajay

Subjects
Physics - Geophysics
Abstract

The 26 December 2004 Sumatra earthquake (Mw = 9.1) initiated around 30 km depth and ruptured 1300 km of the Indo-Australian Sunda plate boundary. During the Sumatra OBS (ocean bottom seismometer) survey, a wide angle seismic profile was acquired across the epicentral region. A seismic velocity model was obtained from combined travel time tomography and forward modeling. Together with reflection seismic data from the SeaCause II cruise, the deep structure of the source region of the great earthquake is revealed. Four to five kilometers of sediments overlie the oceanic crust at the trench, and the subducting slab can be imaged down to a depth of 35 km. We find a crystalline backstop 120 km from the trench axis, below the fore arc basin. A high velocity zone at the lower landward limit of the raycovered domain, at 22 km depth, marks a shallow continental Moho, 170 km from the trench. The deep structure obtained from the seismic data was used to construct a thermal model of the fore arc in order to predict the limits of the seismogenic zone along the plate boundary fault. Assuming 100C-150C as its updip limit, the seismogenic zone is predicted to begin 530 km from the trench. The downdip limit of the 2004 rupture as inferred from aftershocks is within the 350C 450C temperature range, but this limit is 210-250 km from the trench axis and is much deeper than the fore arc Moho. The deeper part of the rupture occurred along the contact between the mantle wedge and the downgoing plate.

Published
2010
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7. Reconstruction of the 1908 Messina gravity flow (central Mediterranean Sea) from geophysical and sedimentological data

Author

Schulten, I., Micallef, A., Krastel, S., Urlaub, M., Gutscher, Marc-andre, Kopp, H., Schulten, I., Micallef, A., Krastel, S., Urlaub, M., Gutscher, Marc-andre, and Kopp, H.

Abstract

Earthquakes, tsunamis and gravity flows are common processes offshore Eastern Sicily and pose a significant hazard to coastal communities and infrastructure. The 1908 Messina earthquake and tsunami resulted in >60,000 casualties. It caused a large turbidity current, which broke the Malta-Zante telegraph cable. Yet, this gravity flow remains poorly characterised in terms of its route and flow behaviour. A comprehensive analysis of multibeam echosounder data, sub-bottom profiles, and sediment cores has been carried out to improve our understanding about gravity flow activity within conduit systems of the western Ionian Basin to reconstruct the characteristics of the 1908 sediment flow (e.g., erosion, velocity, source region). Three main canyon-channel systems can be distinguished within the study area. The easternmost system (C3) appears to be the most active in terms of sediment transport. There are numerous erosional and depositional bedforms, including large-scale scours (>100 m-long), turbidite sediment waves and channel wall collapses that are not overprinted by younger events. The other two canyon-channel systems (C1, C2) do not show many bedforms indicative of repeated and recent gravity flow activity. Indeed, the transport of the majority of sediment discharged into the western system (C1) is limited to <25 km downslope from the continental slope, while the central system (C2) facilitates sediment deposition from gravity flows. C3 is, thus, suggested to have been the main passageway of the 1908 sediment flow. It also leads directly to two of three cable break locations. The most likely source areas for the gravity flow are north-eastern Sicily and southern Calabria. Bedforms indicate a flow thickness of >170 m along the upper channel portion of C3 and > 140 m along its lower portion close to the cable breaks. An average flow velocity of 5.6 to 6.3 ms−1 is reconstructed, given the timing of the breaks and length of the canyon-channel system. The flow may have l

Published
2023
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8. Detecting strain with a fiber optic cable on the seafloor offshore Mount Etna, Southern Italy

Author

Gutscher, Marc-andre, Quetel, Lionel, Murphy, Shane, Riccobene, Giorgio, Royer, Jean-yves, Barreca, Giovanni, Aurnia, Salvatore, Klingelhoefer, Frauke, Cappelli, Giuseppe, Urlaub, Morelia, Krastel, Sebastian, Gross, Felix, Kopp, Heidrun, Gutscher, Marc-andre, Quetel, Lionel, Murphy, Shane, Riccobene, Giorgio, Royer, Jean-yves, Barreca, Giovanni, Aurnia, Salvatore, Klingelhoefer, Frauke, Cappelli, Giuseppe, Urlaub, Morelia, Krastel, Sebastian, Gross, Felix, and Kopp, Heidrun

Abstract

Oceans cover more than 70 percent of the Earth's surface making it difficult and costly to deploy modern seismological instruments here. The rapidly expanding global network of submarine telecom cables offers tremendous possibilities for seismological monitoring using laser light. Recent pioneer studies have demonstrated earthquake detection using lasers in onland and submarine fiber optic cables. However, permanent strain at the seafloor has never before been measured directly as it happens. With this aim, we deployed a dedicated 6-km-long fiber optic strain cable, offshore Catania Sicily, in 2000 m water depth, and connected it to a 29-km long electro-optical cable for science use. We report here that deformation of the cable equivalent to a total elongation of 2.5 cm was observed over a 21-month period (from Oct. 2020 to Jul. 2022). Brillouin laser reflectometry observations over the first 10 months indicate significant strain (+25 to +40 microstrain) at two locations where the cable crosses an active strike-slip fault on the seafloor, with most of the change occurring between 19 and 21 Nov. 2020. The cause of the strain could be fault slip or seabottom currents. During the following 11 months, the strain amplitude increased to +45 to +55 microstrain, affecting a longer portion of the cable up to 500 m to either side of the first fault crossing. A sandbag experiment performed on the distal portion of the cable (3.2–6.0 km) starting Sept. 2021 demonstrates how the fiber optic cable deforms in response to an applied load and how the deformation signal partially dissipates over time due to the elastic properties of the cable. These preliminary results are highly encouraging for the use of BOTDR (Brillouin Optical Time Domain Reflectometry) laser reflectometry as a technique to detect strain at the seafloor in near real time and to monitor the structural health of submarine cables.

Published
2023
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9. Earthquake monitoring in Italy: integration of a temporary seismic experiment into national real-time surveillance, the example of FocusX temporary land-network

Author

Margheriti, Lucia, Moretti, Milena, Piccinini, Davide, Latorre, Diana, Alparone, Salvatore, Cocina, Ornella, Costanzo, Antonio, Gutscher, Marc-andre, La Rocca, Mario, Marchetti, Alessandro, Murphy, Shane, Nardi, Anna, Pastori, Marina, Focus Working Group, Margheriti, Lucia, Moretti, Milena, Piccinini, Davide, Latorre, Diana, Alparone, Salvatore, Cocina, Ornella, Costanzo, Antonio, Gutscher, Marc-andre, La Rocca, Mario, Marchetti, Alessandro, Murphy, Shane, Nardi, Anna, Pastori, Marina, and Focus Working Group

Abstract

The INGV is the operational center for earthquake monitoring in Italy, https://www.ingv.it/en/monitoraggio-e-infrastrutture/sorveglianza/servizio-di-sorveglianza-sismica, it operates the Italian National Seismic Network and other networks at different scales and is a primary node of EIDA for archiving and distributing seismic recordings. INGV provides earthquake information to the Department of Civil Protection and to the public. In the frame of the FOCUS (Fiber Optic Cable Use for seafloor studies of earthquake hazard and deformation) project, https://www.geo-ocean.fr/Recherche/Projets-de-Recherche/ERC-FOCUS, we deployed a temporary seismic network, FXLand (1J), for a passive seismological experiment to record regional seismicity and teleseismic events. This experiment aims to improve the detection of seismicity; the accuracy of earthquake locations, and to define the crustal structure of the region. The seismicity in the Ionian area is possibly the result of two types of tectonic activity at different depths: a gently NW dipping subduction interface of the Calabrian subduction zone, and the strike-slip fault systems in the Ionian Sea, well expressed in the morpho-bathymetry and observed in previous seismic profiles.

Published
2023

14. Towards the new Thematic Core Service Tsunami within the EPOS Research Infrastructure

Author

Babeyko, Andrey, Lorito, Stefano, Hernandez, Francisco, Lauterjungl, Joern, Lovholt, Finn, Rudloff, Alexander, Sorensen, Mathilde, Androsov, Alexey, Aniel-quiroga, Inigo, Armigliato, Alberto, Baptista, Maria Ana, Baglione, Enrico, Basili, Roberto, Behrens, Joern, Brizuela, Beatriz, Brunie, Sergio, Cambaz, M. Didem, Cantavella-nadal, Juan, Carrilho, Fernando, Chandler, Ian, Chang-seng, Denis, Charalampakis, Marinos, Cugliari, Lorenzo, Denamie, Clea, Dogan, Gozde Guney, Festa, Gaetano, Fuhrman, David, Gabriel, Alice-agnes, Galea, Pauline, Gibbons, Steven J., Gonzalez, Mauricio, Graziani, Laura, Gutscher, Marc-andre, Harig, Sven, Hebert, Helen, Ionescu, Constantin, Jalayer, Fatemeh, Kalligeris, Nikos, Kanoglu, Utku, Lanucara, Piero, Macias Sanchez, Jorge, Murphy, Shane, Necmioglu, Ocal, Omira, Rachid, Papadopoulos, Gerassimos A., Paris, Raphael, Romano, Fabrizio, Rossetto, Tiziana, Selva, Jacopo, Scala, Antonio, Tonini, Roberto, Trevlopoulos, Konstantinos, Triantafyllou, Ioanna, Urgeles, Roger, Vallone, Roberto, Vilibic, Ivica, Volpe, Manuela, Yalciner, Ahmet C., Babeyko, Andrey, Lorito, Stefano, Hernandez, Francisco, Lauterjungl, Joern, Lovholt, Finn, Rudloff, Alexander, Sorensen, Mathilde, Androsov, Alexey, Aniel-quiroga, Inigo, Armigliato, Alberto, Baptista, Maria Ana, Baglione, Enrico, Basili, Roberto, Behrens, Joern, Brizuela, Beatriz, Brunie, Sergio, Cambaz, M. Didem, Cantavella-nadal, Juan, Carrilho, Fernando, Chandler, Ian, Chang-seng, Denis, Charalampakis, Marinos, Cugliari, Lorenzo, Denamie, Clea, Dogan, Gozde Guney, Festa, Gaetano, Fuhrman, David, Gabriel, Alice-agnes, Galea, Pauline, Gibbons, Steven J., Gonzalez, Mauricio, Graziani, Laura, Gutscher, Marc-andre, Harig, Sven, Hebert, Helen, Ionescu, Constantin, Jalayer, Fatemeh, Kalligeris, Nikos, Kanoglu, Utku, Lanucara, Piero, Macias Sanchez, Jorge, Murphy, Shane, Necmioglu, Ocal, Omira, Rachid, Papadopoulos, Gerassimos A., Paris, Raphael, Romano, Fabrizio, Rossetto, Tiziana, Selva, Jacopo, Scala, Antonio, Tonini, Roberto, Trevlopoulos, Konstantinos, Triantafyllou, Ioanna, Urgeles, Roger, Vallone, Roberto, Vilibic, Ivica, Volpe, Manuela, and Yalciner, Ahmet C.

Abstract

Tsunamis constitute a significant hazard for European coastal populations, and the impact of tsunami events worldwide can extend well beyond the coastal regions directly affected. Understanding the complex mechanisms of tsunami generation, propagation, and inundation, as well as managing the tsunami risk, requires multidisciplinary research and infrastructures that cross national boundaries. Recent decades have seen both great advances in tsunami science and consolidation of the European tsunami research community. A recurring theme has been the need for a sustainable platform for coordinated tsunami community activities and a hub for tsunami services. Following about three years of preparation, in July 2021, the European tsunami community attained the status of Candidate Thematic Core Service (cTCS) within the European Plate Observing System (EPOS) Research Infrastructure. Within a transition period of three years, the Tsunami candidate TCS is anticipated to develop into a fully operational EPOS TCS. We here outline the path taken to reach this point, and the envisaged form of the future EPOS TCS Tsunami. Our cTCS is planned to be organised within four thematic pillars: (1) Support to Tsunami Service Providers, (2) Tsunami Data, (3) Numerical Models, and (4) Hazard and Risk Products. We outline how identified needs in tsunami science and tsunami risk mitigation will be addressed within this structure and how participation within EPOS will become an integration point for community development.

Published
2022
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15. Assessing the rate of crustal extension by 2D sequential restoration analysis: A case study from the active portion of the Malta Escarpment

Author

Gambino, Salvatore, Barreca, Giovanni, Gross, Felix, Monaco, Carmelo, Gutscher, Marc-andre, Alsop, G. Ian, Gambino, Salvatore, Barreca, Giovanni, Gross, Felix, Monaco, Carmelo, Gutscher, Marc-andre, and Alsop, G. Ian

Abstract

Tectono-stratigraphic interpretation and sequential restoration modelling was performed over two high-resolution seismic profiles crossing the Western Ionian Basin of southern Italy. This analysis was undertaken in order to provide greater insights and a more reliable assessment of the deformation rate affecting the area. Offshore seismic profiling illuminates the sub-seafloor setting where a belt of active normal faults slice across the foot of the Malta Escarpment, a regional-scale structural boundary inherited from the Permo-Triassic palaeotectonic setting. A sequential restoration workflow was established to back-deform the entire investigated sector with the primary aim of analysing the deformation history of the three major normal faults affecting the area. Restoration of the tectono-stratigraphic model reveals how deformation rates evolved through time. In the early stage, the studied area experienced a significant deformation with the horizontal component prevailing over the vertical element. In this context, the three major faults contribute to only one third of the total deformation. The overall throw and extension then notably reduced through time towards the present day and, since the middle Pliocene, ongoing crustal deformation is accommodated almost entirely by the three major normal faults. Unloading and decompaction indicate that when compared to the unrestored seismic sections, a revision and a reduction of roughly one third of the vertical displacement of the faults offset is required. This analysis ultimately allows us to better understand the seismic potential of the region.

Published
2022
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19. Monitoring a submarine strike-slip fault, using a fiber optic strain cable

Author

Gutscher, Marc-Andre, primary, Royer, Jean-Yves, additional, Graindorge, David, additional, Murphy, Shane, additional, Klingelhoefer, Frauke, additional, Gaillot, Arnaud, additional, Aiken, Chastity, additional, Cattaneo, Antonio, additional, Barreca, Giovanni, additional, Quetel, Lionel, additional, Riccobene, Giorgio, additional, Aurnia, Salvatore, additional, Margheriti, Lucia, additional, Moretti, Milena, additional, Krastel, Sebastian, additional, Petersen, Florian, additional, Urlaub, Morelia, additional, Kopp, Heidrun, additional, Currenti, Gilda, additional, and Jousset, Philippe, additional

Published
2022
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23. First deployment of a 6-km long fiber-optic strain cable and a seafloor geodetic network, across an active submarine fault (offshore Catania, Sicily): The FOCUS experiment

Author

Gutscher, Marc-Andre, primary, Royer, Jean-Yves, additional, Murphy, Shane, additional, Klingelhoefer, Frauke, additional, Barreca, Giovanni, additional, Gaillot, Arnaud, additional, Quetel, Lionel, additional, Riccobene, Giorgio, additional, Aurnia, Salvatore, additional, Jousset, Philippe, additional, Poitou, Charles, additional, and Ciausu, Viorel, additional

Published
2021
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24. Geometry of the deep Calabrian subduction (Central Mediterranean Sea) from wide‐angle seismic data and 3‐D gravity modeling

Author

Dellong, David, Klingelhoefer, Frauke, Dannowski, Anke, Kopp, Heidrun, Murphy, Shane, Graindorge, David, Margheriti, Lucia, Moretti, Milena, Barreca, Giovanni, Scarfì, Luciano, Polonia, Alina, Gutscher, Marc-andre, Dellong, David, Klingelhoefer, Frauke, Dannowski, Anke, Kopp, Heidrun, Murphy, Shane, Graindorge, David, Margheriti, Lucia, Moretti, Milena, Barreca, Giovanni, Scarfì, Luciano, Polonia, Alina, and Gutscher, Marc-andre

Abstract

The Calabrian subduction zone is one of the narrowest arcs on Earth and a key area to understand the geodynamic evolution of the Mediterranean and other marginal seas. Here in the Ionian Sea, the African plate subducts beneath Eurasia. Imaging the boundary between the downgoing slab and the upper plate along the Calabrian subduction zone is important for assessing the potential of the subduction zone to generate mega‐thrust earthquakes and was the main objective of this study. Here we present and analyze the results from a 380 km long, wide‐angle seismic profile spanning the complete subduction zone, from the deep Ionian Basin and the accretionary wedge to NE Sicily, with additional constraints offered by 3‐D Gravity modeling and the analysis of earthquake hypocenters. The velocity model for the wide‐angle seismic profile images thin oceanic crust throughout the basin. The Calabrian backstop extends underneath the accretionary wedge to about 100 km SE of the coast. The seismic model was extended in depth using earthquake hypocenters. The combined results indicate that the slab dip increases abruptly from 2‐3° to 60‐70° over a distance of ≤50 km underneath the Calabrian backstop. This abrupt steepening is likely related to the roll‐back geodynamic evolution of the narrow Calabrian slab which shows great similarity to the shallow and deep geometry of the Gibraltar slab. Plain language abstract We investigate the deep crustal structure of southern Italy and the Central Mediterranean where some of the oldest oceanic crust on Earth is actively descending (subducting) into the earth's interior (Speranza et al., 2012). This process causes much of the moderate seismicity observed in this region and may be responsible for strong historical earthquakes as well (Gutscher et al., 2006). Deep seismic data recorded during a marine geophysical expedition performed in 2014, allow us to reconstruct the 3‐D geometry of this subduction zone. Our data reveal a 1‐4 km thick evaporitic (

Published
2020
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25. Reply to Comment by A. Argnani on 'Geometry of the Deep Calabrian Subduction from Wide‐Angle Seismic Data and 3‐D Gravity Modeling'

Author

Dellong, David, Klingelhoefer, Frauke, Dannowski, Anke, Kopp, Heidrun, Murphy, Shane, Graindorge, David, Margheriti, Lucia, Moretti, Milena, Barreca, Giovanni, Scarfì, Luciano, Polonia, Alina, Gutscher, Marc-andre, Dellong, David, Klingelhoefer, Frauke, Dannowski, Anke, Kopp, Heidrun, Murphy, Shane, Graindorge, David, Margheriti, Lucia, Moretti, Milena, Barreca, Giovanni, Scarfì, Luciano, Polonia, Alina, and Gutscher, Marc-andre

Abstract

Andrea Argnani in his comment on Dellong et al., 2020 (Geometry of the deep Calabrian subduction (Central Mediterranean Sea) from wide‐angle seismic data and 3D gravity modeling), proposes an alternate interpretation of the wide‐angle seismic velocity models presented by Dellong et al., 2018 and Dellong et al., 2020 and proposes a correction of the literature citations in these paper. In this reply, we discuss in detail all points raised by Andrea Argnani.

Published
2020
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26. The FOCUS experiment 2020 (Fiber Optic Cable Use for Seafloor studies of earthquake hazard and deformation)

Author

Gutscher, Marc-Andre, Royer, Jean-Yves, Graindorge, David, Murphy, Shane, Klingelhoefer, Frauke, Aiken, Chastity, Cattaneo, Antonio, Barreca, Giovanni, Quetel, Lionel, Riccobene, Giorgio, Aurnia, Salvatore, Petersen, Florian, Lange, Dietrich, Urlaub, Morelia, Krastel, Sebastian, Gross, Felix, Kopp, Heidrun, Moretti, Milena, Beranzoli, Laura, Lo Bue, Nadia, Gutscher, Marc-Andre, Royer, Jean-Yves, Graindorge, David, Murphy, Shane, Klingelhoefer, Frauke, Aiken, Chastity, Cattaneo, Antonio, Barreca, Giovanni, Quetel, Lionel, Riccobene, Giorgio, Aurnia, Salvatore, Petersen, Florian, Lange, Dietrich, Urlaub, Morelia, Krastel, Sebastian, Gross, Felix, Kopp, Heidrun, Moretti, Milena, Beranzoli, Laura, and Lo Bue, Nadia

Abstract

Laser reflectometry (BOTDR), commonly used for structural health monitoring (bridges, dams, etc.), for the first time is being tested to study movements of an active fault on the seafloor, 25 km offshore Catania Sicily (an urban area of 1 million people). Under ideal conditions, this technique can measure small strains (10E-6), across very large distances (10 - 200 km) and locate these strains with a spatial resolution of 10 - 50 m. As the first experiment of the European funded FOCUS project (ERC Advanced Grant), in late April 2020 we aimed to connect and deploy a dedicated 6-km long strain cable to the TSS (Test Site South) seafloor observatory in 2100 m water depth operated by INFN-LNS (Italian National Physics Institute). The work plan for the marine expedition FocusX1 onboard the research vessel PourquoiPas? is described here. First, microbathymetric mapping and a video camera survey are performed by the ROV Victor6000. Then, several intermediate junction frames and short connector cables (umbilicals) are connected. A cable-end module and 6-km long fiber-optic strain cable (manufactured by Nexans Norway) is then connected to the new junction box. Next, we use a deep-water cable-laying system with an integrated plow (updated Deep Sea Net design Ifremer, Toulon) to bury the cable 20 cm in the soft sediments in order to increase coupling between the cable and the seafloor. The targeted track for the cable crosses the North Alfeo Fault at three locations. Laser reflectometry measurements began April 2020 and will be calibrated by a three-year deployment of seafloor geodetic instruments (Canopus acoustic beacons manufactured by iXblue) also started April 2020, to quantify relative displacement across the fault. During a future marine expedition, tentatively scheduled for 2021 (FocusX2) a passive seismological experiment is planned to record regional seismicity. This will involve deployment of a temporary network of OBS (Ocean Bottom Seismometers) on the seafloor and

Published
2020

27. Late Quaternary co-seismic sedimentation in the Sea of Marmara's deep basins

Author

Beck, Christian, Mercier de Lépinay, Bernard, Schneider, Jean-Luc, Cremer, Michel, Çağatay, Namik, Wendenbaum, Evrard, Boutareaud, Sébastien, Ménot, Guillemette, Schmidt, Sabine, Weber, Olivier, Eris, Kadir, Armijo, Rolando, Meyer, Bertrand, Pondard, Nicolas, Gutscher, Marc-André, Turon, J.-L., Labeyrie, L., Cortijo, E., Gallet, Y., Bouquerel, Hélène, Gorur, N., Gervais, A., Castera, M.-H., Londeix, L., de Rességuier, A., and Jaouen, A.

Published
2007
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28. Destruction of Atlantis by a great earthquake and tsunami? A geological analysis of the Spartel Bank hypothesis

Author

Gutscher, Marc-Andre

Subjects
Tsunamis, Earthquakes, Earth sciences
Abstract

Numerous geographical similarities exist between Plato's descriptions of Atlantis and a paleoisland (Spartel) in the western Straits of Gibraltar. The dialogues recount a catastrophic event that submerged the island ca. 11.6 ka in a single day and night, due to violent earthquakes and floods. This sudden destruction is consistent with a great earthquake (M > 8.5) and tsunami, as in the Gulf of Cadiz region in 1755 when tsunami run-up heights reached 10 m. Great earthquakes (M 8-9) and tsunamis occur in the Gulf of Cadiz with a repeat time of 1.5-2 k.y., according to the sedimentary record. An unusually thick turbidite dated as ca. 12 ka may coincide with the destructive event in Plato's account. The detailed morphology of Spartel paleoisland, as determined from recently acquired high-resolution bathymetric data, is reported here. The viability of human habitation on this paleoisland ca. 11.6 ka is discussed on the basis of a new bathymetric map. Keywords: earthquake, tsunami, lberia, paleoseismology, geoarcheology.

Published
2005

30. Reply to Comment by A. Argnani on “Geometry of the Deep Calabrian Subduction From Wide‐Angle Seismic Data and 3‐D Gravity Modeling”

Author

Dellong, David, primary, Klingelhoefer, Frauke, additional, Dannowski, Anke, additional, Kopp, Heidrun, additional, Murphy, Shane, additional, Graindorge, David, additional, Margheriti, Lucia, additional, Moretti, Milena, additional, Barreca, Giovanni, additional, Scarfì, Luciano, additional, Polonia, Alina, additional, and Gutscher, Marc‐Andre, additional

Published
2020
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31. Geometry of the Deep Calabrian Subduction (Central Mediterranean Sea) From Wide‐Angle Seismic Data and 3‐D Gravity Modeling

Author

Dellong, David, primary, Klingelhoefer, Frauke, additional, Dannowski, Anke, additional, Kopp, Heidrun, additional, Murphy, Shane, additional, Graindorge, David, additional, Margheriti, Lucia, additional, Moretti, Milena, additional, Barreca, Giovanni, additional, Scarfì, Luciano, additional, Polonia, Alina, additional, and Gutscher, Marc‐Andre, additional

Published
2020
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32. Can slab melting be caused by flat subduction?

Author

Gutscher, Marc-Andre, Maury, Rene, Eissen, Jean-Philippe, and Bourdon, Erwan

Subjects
South America -- Natural history, Subduction zones (Geology) -- Research, Magmatism -- Research, Magma -- Environmental aspects, Earth sciences
Abstract

Slab melting has been suggested as a likely source of adakitic arc magmas (i.e., andesitic and dacitic magmas strongly depleted in Y and heavy rare earth elements). Existing numerical and petrologic models, however, restrict partial melting to very young ( Keywords: flat subduction, thermal structure, slab melting, adakites.

Published
2000

34. Marine Transform Faults And Fracture Zones: A Joint Perspective Integrating Seismicity, Fluid Flow And Life

Author

Hensen, Christian, Duarte, Joao C., Vannucchi, Paola, Mazzini, Adriano, Lever, Mark A., Terrinha, Pedro, Geli, Louis, Henry, Pierre, Villinger, Heinrich, Morgan, Jason, Schmidt, Mark, Gutscher, Marc-Andre, Bartolome, Rafael, Tomonaga, Yama, Polonia, Alina, Gracia, Eulalia, Tinivella, Umberta, Lupi, Matteo, Cagatay, M. Namik, and Elvert, Marcus

Abstract

Marine transform faults and associated fracture zones (MTFFZs) cover vast stretches of the ocean floor, where they play a key role in plate tectonics, accommodating the lateral movement of tectonic plates and allowing connections between ridges and trenches. Together with the continental counterparts of MTFFZs, these structures also pose a risk to human societies as they can generate high magnitude earthquakes and trigger tsunamis. Historical examples are the Sumatra-Wharton Basin Earthquake in 2012 (M8.6) and the Atlantic Gloria Fault Earthquake in 1941 (M8.4). Earthquakes at MTFFZs furthermore open and sustain pathways for fluid flow triggering reactions with the host rocks that may permanently change the rheological properties of the oceanic lithosphere. In fact, they may act as conduits mediating vertical fluid flow and leading to elemental exchanges between Earth's mantle and overlying sediments. Chemicals transported upward in MTFFZs include energy substrates, such as H-2 and volatile hydrocarbons, which then sustain chemosynthetic, microbial ecosystems at and below the seafloor. Moreover, up-or downwelling of fluids within the complex system of fractures and seismogenic faults along MTFFZs could modify earthquake cycles and/or serve as "detectors" for changes in the stress state during interseismic phases. Despite their likely global importance, the large areas where transform faults and fracture zones occur are still underexplored, as are the coupling mechanisms between seismic activity, fluid flow, and life. This manuscript provides an interdisciplinary review and synthesis of scientific progress at or related to MTFFZs and specifies approaches and strategies to deepen the understanding of processes that trigger, maintain, and control fluid flow at MTFFZs.

Published
2019

35. Applying laser reflectometry to study active submarine faults: the FOCUS project (FOCUS = Fiber Optic Cable Use for Seafloor studies of earthquake hazard and deformation)

Author

Gutscher, Marc-Andre, Royer, Jean-Yves, Graindorge, David, Murphy, Shane, Klingelhoefer, Frauke, Aiken , Chastity, Cattaneo, Antonio, Barreca, Giovanni, Lionel, Quetel, Giorgio, Riccobene, Petersen, Florian, Urlaub, Morelia, Krastel-Gudegast, Sebastian, Gross, Felix, Kopp, Heidrun, Milena, Moretti, and Laura, Berenzoli

Abstract

Laser reflectometry (BOTDR), commonly used for structural health monitoring (bridges, dams, etc.), will for the first time be applied to study movements of an active fault on the seafloor, 25 km offshore Catania Sicily (an urban area of 1 million people). This technique can measure and locate micro-strains (< 1 mm) across very large distances (10 - 200 km). The goal of the European funded FOCUS project (ERC Advanced Grant) is to connect a dedicated 6-km long strain cable to the EMSO (European Multidisciplinary water-column and Seafloor Observatory) seafloor observatory in 2100 m water depth. Here, in May 2017, between the onshore fault system on the SE flank of Mount Etna and the deeper offshore Alfeo fault system, 4 cm of dextral strike-slip movement was documented as a slow slip event by seafloor acoustic ranging. For the planned seafloor operations, a detailed site survey of the seafloor will first be performed to determine the best path for deployment of the new strain cable. The next step will be to connect this 6-km long fiber optic cable to the EMSO station TSS (Test Site South) using a deep-water cable-laying system with an integrated plow to bury the cable 20 cm in the soft sediments in order to increase coupling between the cable and the seafloor. The targeted track for the cable will cross the North Alfeo Fault at three locations. Laser reflectometry measurements will be calibrated by a three-year deployment of seafloor geodetic instruments to quantify relative displacement across the fault. During the implementation of the laser reflectometry, a passive seismological experiment is planned to record regional seismicity. This will involve deployment of a temporary network of OBS (Ocean Bottom Seismometers) on the seafloor and seismic stations on land, supplemented by INGV permanent land stations. The simultaneous use of laser reflectometry, seafloor geodetic stations as well as seismological land and sea stations will provide an integrated system for monitoring a wide range of types of slipping events along the North Alfeo Fault. A long-term goal is the development of dual-use telecom cables with industry partners.

Published
2019

37. Ionian Abyssal Plain: A window into the Tethys oceanic lithosphere

Author

Dannowski, Anke, Kopp, Heidrun, Klingelhoefer, Frauke, Klaeschen, Dirk, Gutscher, Marc-andre, Krabbenhoeft, Anne, Dellong, David, Rovere, Mickael, Graindorge, David, Papenberg, Cord, Klaucke, Ingo, Dannowski, Anke, Kopp, Heidrun, Klingelhoefer, Frauke, Klaeschen, Dirk, Gutscher, Marc-andre, Krabbenhoeft, Anne, Dellong, David, Rovere, Mickael, Graindorge, David, Papenberg, Cord, and Klaucke, Ingo

Abstract

The nature of the Ionian Sea crust has been the subject of scientific debate for more than 30 years, mainly because seismic imaging of the deep crust and upper mantle of the Ionian Abyssal Plain (IAP) has not been conclusive to date. The IAP is sandwiched between the Calabrian and Hellenic subduction zones in the central Mediterranean. To univocally confirm the proposed oceanic nature of the IAP crust as a remnant of the Tethys ocean and to confute its interpretation as a strongly thinned part of the African continental crust, a NE-SW oriented 131 km long seismic refraction and wide-angle reflection profile consisting of eight ocean bottom seismometers and hydrophones was acquired in 2014. A P-wave velocity model developed from travel time forward modelling is refined by gravimetric data and synthetic modelling of the seismic data. A roughly 6km thick crust with velocities ranging from 5.1km/s to 7.2km/s, top to bottom, can be traced throughout the IAP. In the vicinity of the Medina Seamounts at the southern IAP boundary, the crust thickens to about 9km and seismic velocities decrease to 6.8km/s at the crust-mantle boundary. The seismic velocity distribution and depth of the crust-mantle boundary in the IAP document its oceanic nature, and support the interpretation of the IAP as a remnant of the Tethys oceanic lithosphere formed during the Permian and Triassic period.

Published
2019
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38. Fiber optic monitoring of active faults at the seafloor: I the FOCUS project

Author

Gutscher, Marc-andre, Royer, Jean-yves, Graindorge, David, Murphy, Shane, Klingelhoefer, Frauke, Aiken, Chastity, Cattaneo, Antonio, Barreca, Giovanni, Quetel, Lionel, Riccobene, Giorgio, Petersen, Florian, Urlaub, Morelia, Krastel, Sebastian, Gross, Felix, Kopp, Heidrun, Margheriti, Lucia, Beranzoli, Laura, Gutscher, Marc-andre, Royer, Jean-yves, Graindorge, David, Murphy, Shane, Klingelhoefer, Frauke, Aiken, Chastity, Cattaneo, Antonio, Barreca, Giovanni, Quetel, Lionel, Riccobene, Giorgio, Petersen, Florian, Urlaub, Morelia, Krastel, Sebastian, Gross, Felix, Kopp, Heidrun, Margheriti, Lucia, and Beranzoli, Laura

Abstract

Laser reflectometry (BOTDR), commonly used for structural health monitoring (bridges, dams, etc.), will for the first time be applied to study movements of an active fault on the seafloor 25 km offshore Catania Sicily. The goal of the European funded FOCUS project (ERC Advanced Grant) is to connect a 6-km long strain cable to the EMSO seafloor observatory in 2100 m water depth. Laser observations will be calibrated by seafloor geodetic instruments and seismological stations. A long-term goal is the development of dual-use telecom cables with industry partners.

Published
2019
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39. The Alpine Orogeny in the West and Southwest Iberia Margins

Author

Quesada, Cecilio, Oliveira, José Tomás, Terrinha, Pedro, Ramos, Adrià, Neres, Marta, Valadares, Vasco, Duarte, João, Martínez-Loriente, Sara, Silva, Sónia, Mata, João, Kullberg, José Carlos, Casas-Sainz, Antonio, Matias, Luís, Fernández, Óscar, Muñoz, Josep Anton, Ribeiro, Carlos, Font, Eric, Neves, Conceição, Roque, Cristina, Rosas, Filipe, Pinheiro, Luís, Bartolomé, Rafael, Sallarès, Valentí, Magalhães, Vítor, Medialdea, Teresa, Somoza, Luis, Gràcia, Eulàlia, Hensen, Christian, Gutscher, Marc-Andre, Ribeiro, António, Zitellini, Nevio, Quesada, Cecilio, Oliveira, José Tomás, Terrinha, Pedro, Ramos, Adrià, Neres, Marta, Valadares, Vasco, Duarte, João, Martínez-Loriente, Sara, Silva, Sónia, Mata, João, Kullberg, José Carlos, Casas-Sainz, Antonio, Matias, Luís, Fernández, Óscar, Muñoz, Josep Anton, Ribeiro, Carlos, Font, Eric, Neves, Conceição, Roque, Cristina, Rosas, Filipe, Pinheiro, Luís, Bartolomé, Rafael, Sallarès, Valentí, Magalhães, Vítor, Medialdea, Teresa, Somoza, Luis, Gràcia, Eulàlia, Hensen, Christian, Gutscher, Marc-Andre, Ribeiro, António, and Zitellini, Nevio

Abstract

The Alpine orogeny is well recorded onshore and offshore by tectonic inversion of the Mesozoic rift basins. Large scale linear seamounts (more than 250 km long and with up to 5 km of uplift) involving oceanic and continental lithosphere were carried on top of thrusts, such as the Gorringe seamount and the Estremadura Spur in the SouthWest and West Iberia Margin, respectively. The SouthWest Iberia Margin also recorded the westward migration of the Gibraltar Oceanic slab as the westwards propagation of the Neo-Tethys subduction. Rotation of the tectonic compression from NW-SE to WNW-ESE inPliocene times caused the development of large scale dextral wrench faults as the present day Africa-Iberia plate boundary. Neotectonics of this plate boundary caused large to mega-scale destructive earthquakes and tsunamis.

Published
2019

40. Ionian Abyssal Plain: A window into the Tethys oceanic lithosphere

Author

Kopp, Heidrun, Dannowski, Anke, Klingelhoefer, Frauke, Klaeschen, Dirk, Gutscher, Marc-Andre, Krabbenhoeft, Anne, Dellong, David, Rovere, Marzia, Graindorge, David, Papenberg, Cord, Klaucke, Ingo, Kopp, Heidrun, Dannowski, Anke, Klingelhoefer, Frauke, Klaeschen, Dirk, Gutscher, Marc-Andre, Krabbenhoeft, Anne, Dellong, David, Rovere, Marzia, Graindorge, David, Papenberg, Cord, and Klaucke, Ingo

Published
2019

43. The source of the Lisbon earthquake

Author

Fonseca, Joao F.B.D. and Gutscher, Marc-Andre

Subjects
Science and technology
Abstract

IN HIS PERSPECTIVE 'WHAT CAUSED THE Great Lisbon earthquake?' (27 Aug. 2004, p. 1247) M.-A. Gutscher proposes an eastward-dipping subduction zone under the Straits of Gibraltar as a likely candidate [...]

Published
2005

46. Active tectonics of the Calabrian subduction revealed by new multi-beam bathymetric data and high-resolution seismic profiles in the Ionian Sea (Central Mediterranean)

Author

Gutscher, Marc-André, Kopp, Heidrun, Krastel, Sebastian, Bohrmann, Gerhard, Garlan, Thierry, Zaragosi, Sebastien, Klaucke, Ingo, Wintersteller, Paul, Loubrieu, Benoit, Le Faou, Yann, San Pedro, Laurine, Dominguez, Stephane, Rovere, Marzia, Mercier de Lepinay, Bernard, Ranero, Cesar, and Sallares, Valenti

Published
2017
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47. Evidence of the Zanclean megaflood in the eastern Mediterranean Basin

Author

Micallef, Aaron, Camerlenghi, Angelo, Garcia-castellanos, Daniel, Otero, Daniel Cunarro, Gutscher, Marc-andre, Barreca, Giovanni, Spatola, Daniele, Facchin, Lorenzo, Geletti, Riccardo, Krastel, Sebastian, Gross, Felix, Urlaub, Morelia, Micallef, Aaron, Camerlenghi, Angelo, Garcia-castellanos, Daniel, Otero, Daniel Cunarro, Gutscher, Marc-andre, Barreca, Giovanni, Spatola, Daniele, Facchin, Lorenzo, Geletti, Riccardo, Krastel, Sebastian, Gross, Felix, and Urlaub, Morelia

Abstract

The Messinian salinity crisis (MSC) - the most abrupt, global-scale environmental change since the end of the Cretaceous - is widely associated with partial desiccation of the Mediterranean Sea. A major open question is the way normal marine conditions were abruptly restored at the end of the MSC. Here we use geological and geophysical data to identify an extensive, buried and chaotic sedimentary body deposited in the western Ionian Basin after the massive Messinian salts and before the Plio-Quaternary open-marine sedimentary sequence. We show that this body is consistent with the passage of a megaflood from the western to the eastern Mediterranean Sea via a south-eastern Sicilian gateway. Our findings provide evidence for a large amplitude drawdown in the Ionian Basin during the MSC, support the scenario of a Mediterranean-wide catastrophic flood at the end of the MSC, and suggest that the identified sedimentary body is the largest known megaflood deposit on Earth.

Published
2018
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48. Crustal structure of the Ionian basin and eastern Sicily margin: results from a wide-angle seismic survey.

Author

Dellong, David, Klingelhoefer, Frauke, Kopp, Heidrun, Graindorge, David, Margheriti, Lucia, Moretti, Milena, Murphy, Shane, Gutscher, Marc-andre, Dellong, David, Klingelhoefer, Frauke, Kopp, Heidrun, Graindorge, David, Margheriti, Lucia, Moretti, Milena, Murphy, Shane, and Gutscher, Marc-andre

Abstract

In the Ionian Sea (Central Mediterranean) the slow convergence between Africa and Eurasia results in the formation of a narrow subduction zone. The nature of the crust of the subducting plate remains debated and could represent the last remnants of the Neo-Tethys ocean. The origin of the Ionian basin is also under discussion, especially concerning the rifting mechanisms as the Malta Escarpment could represent a remnant of this opening. This subduction retreat toward the south-east (motion occurring since the last 35 Ma) but is confined to the narrow Ionian Basin. A major lateral slab tear fault is required to accommodate the slab roll-back. This fault is thought to propagate along the eastern Sicily margin but its precise location remains controversial. This study focuses on the deep crustal structure of the Eastern-Sicily margin and the Malta Escarpment. We present two two-dimensional P-wave velocity models obtained from forward modeling of wide-angle seismic data acquired onboard the R/V Meteor during the DIONYSUS cruise in 2014. The results image an oceanic crust within the Ionian basin as well as the deep structure of the Malta Escarpment, which presents characteristics of a transform margin. A deep and asymmetrical sedimentary basin is imaged south of the Messina strait and seems to have opened between the Calabrian and Peloritan continental terranes. The interpretation of the velocity models suggests that the tear fault is located east of the Malta Escarpment, along the Alfeo fault system (AFS).

Published
2018
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