215 results on '"Petersen, Florian"'
Search Results
2. Interseismic strain build-up on the submarine North Anatolian Fault offshore Istanbul
- Author
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Lange, Dietrich, Kopp, Heidrun, Royer, Jean-Yves, Henry, Pierre, Çakir, Ziyadin, Petersen, Florian, Sakic, Pierre, Ballu, Valerie, Bialas, Jörg, Özeren, Mehmet Sinan, Ergintav, Semih, and Géli, Louis
- Published
- 2019
- Full Text
- View/download PDF
3. The Submarine Boundaries of Mount Etna’s Unstable Southeastern Flank
- Author
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Urlaub, Morelia, Geersen, Jacob, Petersen, Florian, Gross, Felix, Bonforte, Alessandro, Krastel, Sebastian, Kopp, Heidrun, Urlaub, Morelia, Geersen, Jacob, Petersen, Florian, Gross, Felix, Bonforte, Alessandro, Krastel, Sebastian, and Kopp, Heidrun
- Abstract
Coastal and ocean island volcanoes are renowned for having unstable flanks. This can lead to flank deformation on a variety of temporal and spatial scales ranging from slow creep to catastrophic sector collapse. A large section of these unstable flanks is often below sea level, where information on the volcano-tectonic structure and ground deformation is limited. Consequently, kinematic models that attempt to explain measured ground deformation onshore associated with flank instability are poorly constrained in the offshore area. Here, we attempt to determine the locations and the morpho-tectonic structures of the boundaries of the submerged unstable southeastern flank of Mount Etna (Italy). The integration of new marine data (bathymetry, microbathymetry, offshore seismicity, reflection seismic lines) and published marine data (bathymetry, seafloor geodesy, reflection seismic lines) allows identifying the lineament north of Catania Canyon as the southern lateral boundary with a high level of confidence. The northern and the distal (seaward) boundaries are less clear because no microbathymetric or seafloor geodetic data are available. Hypotheses for their locations are presented. Geophysical imaging suggests that the offshore Timpe Fault System is a shallow second-order structure that likely results from extensional deformation within the moving flank. Evidence for active uplift and compression upslope of the amphitheater-shaped depression from seismic data along with subsidence of the onshore Giarre Wedge block observed in ground deformation data leads us to propose that this block is a rotational slump, which moves on top of the large-scale instability. The new shoreline-crossing structural assessment may now inform and improve kinematic models.
- Published
- 2022
- Full Text
- View/download PDF
4. In-situ monitoring of strain on the seafloor: an overview and results of the GeoSEA projects
- Author
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Kopp, Heidrun, primary, Lange, Dietrich, additional, Urlaub, Morelia, additional, Petersen, Florian, additional, and Jegen, Anna, additional
- Published
- 2022
- Full Text
- View/download PDF
5. How to detect slow slip and long-term seafloor deformation? Lessons from two acoustic ranging campaigns on the submerged flank of Mt Etna
- Author
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Petersen, Florian, primary, Urlaub, Morelia, additional, Gross, Felix, additional, Bonforte, Alessandro, additional, and Kopp, Heidrun, additional
- Published
- 2022
- Full Text
- View/download PDF
6. Monitoring a submarine strike-slip fault, using a fiber optic strain cable
- Author
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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
- Full Text
- View/download PDF
7. Repeated mapping and geological sampling of Mt Etna’s submerged continental margin: First results from RV Meteor expedition M178
- Author
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Gross, Felix, primary, Kolling, Henriette, additional, Barrett, Rachel, additional, Hadré, Emma, additional, Heinrich, Mirja, additional, Bonforte, Alessandro, additional, Gambino, Salvatore, additional, Petersen, Florian, additional, Morgenweck, Lea, additional, Matzerath, Peter, additional, Wolf, Josephin, additional, Heinrich, Sven, additional, Vollert, Jannes, additional, Hundsdörfer, Marie, additional, Filbrandt, Christian, additional, and Urlaub, Morelia, additional
- Published
- 2022
- Full Text
- View/download PDF
8. Flank instability at Mount Etna: new insights from seafloor deformation monitoring
- Author
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Urlaub, Morelia, primary, Petersen, Florian, additional, Bonforte, Alessandro, additional, Gross, Felix, additional, and Kopp, Heidrun, additional
- Published
- 2022
- Full Text
- View/download PDF
9. The Submarine Boundaries of Mount Etna’s Unstable Southeastern Flank
- Author
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Urlaub, Morelia, primary, Geersen, Jacob, additional, Petersen, Florian, additional, Gross, Felix, additional, Bonforte, Alessandro, additional, Krastel, Sebastian, additional, and Kopp, Heidrun, additional
- Published
- 2022
- Full Text
- View/download PDF
10. Basin inversion: reactivated rift structures in the central Ligurian Sea revealed using ocean bottom seismometers
- Author
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Thorwart, Martin, Dannowski, Anke, Grevemeyer, Ingo, Lange, Dietrich, Kopp, Heidrun, Petersen, Florian, Crawford, Wayne, Paul, Anne, The Alparray Working Group, Christian-Albrechts-Universität zu Kiel (CAU), Helmholtz Centre for Ocean Research [Kiel] (GEOMAR), Institut de Physique du Globe de Paris (IPGP (UMR_7154)), Institut national des sciences de l'Univers (INSU - CNRS)-Université de La Réunion (UR)-Institut de Physique du Globe de Paris (IPG Paris)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), Institut des Sciences de la Terre (ISTerre), Institut national des sciences de l'Univers (INSU - CNRS)-Institut de recherche pour le développement [IRD] : UR219-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Gustave Eiffel-Université Grenoble Alpes (UGA), LOBSTER project that is part of the German Priority Programme SPP2017 4D-MB, ANR-15-CE31-0015,AlpArray-FR,Voir et comprendre les Alpes en 3D, de la croûte au manteau(2015), Institut de Physique du Globe de Paris (IPGP), and Institut national des sciences de l'Univers (INSU - CNRS)-IPG PARIS-Université de La Réunion (UR)-Centre National de la Recherche Scientifique (CNRS)-Université de Paris (UP)
- Subjects
010504 meteorology & atmospheric sciences ,[SDU.STU.GP]Sciences of the Universe [physics]/Earth Sciences/Geophysics [physics.geo-ph] ,Stratigraphy ,Inversion (geology) ,Soil Science ,Induced seismicity ,010502 geochemistry & geophysics ,01 natural sciences ,Mantle (geology) ,Geochemistry and Petrology ,Thrust fault ,14. Life underwater ,Compression (geology) ,ComputingMilieux_MISCELLANEOUS ,0105 earth and related environmental sciences ,Earth-Surface Processes ,[SDU.STU.TE]Sciences of the Universe [physics]/Earth Sciences/Tectonics ,QE1-996.5 ,Rift ,Continental crust ,Paleontology ,Crust ,Geology ,QE640-699 ,Geophysics ,Seismology - Abstract
The northern margin of the Ligurian Basin shows notable seismicity at the Alpine front, including frequent magnitude 4 events. Seismicity decreases offshore towards the Basin centre and Corsica, revealing a diffuse distribution of low-magnitude earthquakes. We analyse data of the amphibious AlpArray seismic network with focus on the offshore component, the AlpArray ocean bottom seismometer (OBS) network, consisting of 24 broadband OBSs deployed for 8 months, to reveal the seismicity and depth distribution of micro-earthquakes beneath the Ligurian Sea. Two clusters occurred between ∼ 10 km to ∼ 16 km depth below the sea surface, within the lower crust and uppermost mantle. Thrust faulting focal mechanisms indicate compression and an inversion of the Ligurian Basin, which is an abandoned Oligocene–Miocene rift basin. The basin inversion is suggested to be related to the Africa–Europe plate convergence. The locations and focal mechanisms of seismicity suggest reactivation of pre-existing rift-related structures. Slightly different striking directions of presumed rift-related faults in the basin centre compared to faults further east and hence away from the rift basin may reflect the counter-clockwise rotation of the Corsica–Sardinia block. High mantle S-wave velocities and a low Vp/Vs ratio support the hypothesis of strengthening of crust and uppermost mantle during the Oligocene–Miocene rifting-related extension and thinning of continental crust.
- Published
- 2021
11. Basin inversion: Reactivated rift structures in the Ligurian Sea revealed by OBS
- Author
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Thorwart, Martin, Dannowski, Anke, Grevemeyer, Ingo, Lange, Dietrich, Kopp, Heidrun, Petersen, Florian, Crawford, Wayne, and Paul, Anne
- Abstract
The northern margin of the Ligurian Basin shows notable seismicity at the Alpine front, including frequent magnitude 4 events. Seismicity decreases offshore towards the Basin centre and Corsica, revealing a diffuse distribution of low magnitude earthquakes. We analyse data of the amphibious AlpArray seismic network with focus on the offshore component, the AlpArray OBS network, consisting of 24 broadband ocean bottom seismometers deployed for eight months, to reveal the seismicity and depth distribution of micro-earthquakes beneath the Ligurian Sea. Two clusters occurred between ~10 km to ~16 km depth below sea surface, within the lower crust and uppermost mantle. Thrust faulting focal mechanisms indicate compression and an inversion of the Ligurian Basin, which is an abandoned Oligocene rift basin. The Basin inversion is suggested to be related to the Africa-Europe plate convergence. The locations and focal mechanisms of seismicity suggest reactivation of pre-existing rift structures. Slightly different striking directions of faults in the basin centre compared to faults further east and hence away from the abandoned rift may mimic the counter-clockwise rotation of the Corsica-Sardinia block during ~20–16 Ma. The observed cluster events support the hypothesis of strengthening of crust and uppermost mantle during rifting related extension and thinning of continental crust.
- Published
- 2021
12. Analysis of seismic and aseismic deformation using shoreline-crossing observations
- Author
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Petersen, Florian
- Abstract
Localized shear zones accommodate the deformation of the Earth’s surface and are referred to as geological faults. Where the stress of tectonic plate movement or gravitational forces act on the internal strength of rocks or sediments and exceed certain shear stresses, rapid brittle deformation releases elastic energy, in the form of an earthquake. When physical properties, loading rate, or environmental conditions reduce the slip rate, no or long-period seismic energy is radiated and referred to as aseismic deformation. Varying fault slip behavior plays an essential role in the earthquake cycle and poses a significant risk to coastal populations, especially when occurring offshore due to potential cascading effects. The rigorous study of the seismic or aseismic behavior of faults involves the application of seafloor measurements and coastal observations to provide adequate assessments and mitigate future marine geohazards. This thesis aims to analyze offshore seismic and aseismic deformation using different seismological and geodetic constraints from on- and offshore observations to better understand the spatial and temporal variations in fault slip behavior. The main methodology combines marine seismology and seafloor geodesy in a shoreline-crossing approach to estimate the Spatio-temporal slip behavior along two major fault types. The behavior varies from seismic to radiation of elastic energy to aseismic (silent or slow slip), and is estimated to provide constraints on overarching tectonic or geological processes. To decipher slip variation along different fault types and to understand the underlying processes, three distinct settings are investigated: the offshore megathrust along the north Chilean subduction zone, the strike-slip North Anatolian Fault in the central Sea of Marmara and the southern limit of the unstable eastern flank of Europe’s largest active volcano, Mount Etna. The north Chilean subduction zone is characterized by the erosional underthrusting of the oceanic Nazca plate underneath the continental South American plate. The 2014 Mw 8.1 Iquique earthquake sheds light on the subduction processes of the shallow megathrust and the marine forearc. Analysis of an amphibious seismic network and multi-channel seismic data reveals a coupled process involving the seismic behavior at the seismogenic up-dip limit and shallow subduction erosion during the co- and postseismic phase. Aseismic deformation of sub-seafloor faults is ubiquitous and requires the application of seafloor measurement techniques. Direct displacement monitoring using acoustic direct-path ranging is beneficial for in situ detection and discrimination of aseismic and seismic fault displacement. The analysis of seismic activity and deformation on the submerged strike-slip fault zone of the North Anatolian Fault using acoustic direct-path ranging with long-term monitoring revealed the locking state of the central Marmara segment and the implications of strain accumulation for the densely populated region. Gravitational-driven fault displacement in the event of a submarine landslide poses a significant risk to inhabited coastal areas. The eastern flank of Mount Etna in Sicily has long been known for its instability, but offshore constraints were lacking. Analyses of the submerged eastern flank, which is limited by an onshore elongated strike-slip fault to the south, revealed aseismic slip behavior that includes slow slip and demonstrated the potential hazard of sudden flank movement in the Mediterranean Sea.
- Published
- 2021
13. Local seismicity indicates basin inversion in the Ligurian Sea
- Author
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Thorwart, Martin, Dannowski, Anke, Grevemeyer, Ingo, Lange, Dietrich, Kopp, Heidrun, Petersen, Florian, Crawford, Wayne, Paul, Anne, Institute of Geosciences [Kiel], Christian-Albrechts-Universität zu Kiel (CAU), Helmholtz Centre for Ocean Research [Kiel] (GEOMAR), Institut de Physique du Globe de Paris (IPGP), Institut national des sciences de l'Univers (INSU - CNRS)-IPG PARIS-Université Paris Diderot - Paris 7 (UPD7)-Université de La Réunion (UR)-Centre National de la Recherche Scientifique (CNRS), Institut des Sciences de la Terre (ISTerre), Institut national des sciences de l'Univers (INSU - CNRS)-Institut de recherche pour le développement [IRD] : UR219-Université Grenoble Alpes (UGA)-Université Gustave Eiffel-Centre National de la Recherche Scientifique (CNRS)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry]), and ANR-15-CE31-0015,AlpArray-FR,Voir et comprendre les Alpes en 3D, de la croûte au manteau(2015)
- Subjects
[SDU.STU.GP]Sciences of the Universe [physics]/Earth Sciences/Geophysics [physics.geo-ph] - Abstract
International audience; The Alpine orogen and the Apennine system are part of the complex tectonic setting in the Mediterranean Sea caused by the convergence between Africa and Eurasia. Between 30 Ma and 15 Ma the Calabrian subduction retreated in a southeast direction pulling Corsica and Sardinia away from the Eurasian landmass. In this extensional setting, the Ligurian Sea was formed as a back-arc basin. The rifting jumped 15 Ma ago in the Tyrrhenian Sea leaving Corsica and Sardinia in a stable position relative to Eurasia.Within the framework of the AlpArray research initiative a long-term seismological experiment was conducted in the Ligurian Sea to investigate the lithospheric structure and the seismicity in the Ligurian basin. The passive seismic network consisted of 29 broad-band ocean bottom stations from Germany and France. It was in operation between June 2017 and February 2018.Two seismicity clusters occurred in the centre of the Ligurian Basin. The 18 earthquakes are located in the lower crust and in the upper-most mantle at depths between 10 km and 16 km. Re-location was performed only using picks from the OBS in the centre of the Ligurian Sea to avoid artifacts from the complex 3D velocity structure of the basin. Mantle refractions Pn and Sn have apparent velocities of 8.2 km/s and 4.7 km/s. The low Vp-Vs-ratio of 1.72 indicates a more brittle behaviour of the mantle material.Fault plane solutions were determined for four events using also the data of land stations in southern France, Corsica, Sardinia and northern Italy. The focal mechanisms are thrust faulting. Fault planes strike in a NE-SW direction, coinciding with the alignment of the events and the direction of the basin axis.We interprete the two earthquake clusters related to the inversion of the Ligurian Basin where the basin"s centre is under compression and stresses are taken up by reactivated faults in the crust and uppermost mantle. The compressional forces could be caused by the convergence of Africa and Europe. In general, observations of earthquakes in continental mantle lithosphere are rare and they reveal on the one hand a strengthening of the crust and uppermost mantle during rifting and on the other hand they support the interpretation that rifting failed in the northern Ligurian Basin.
- Published
- 2021
14. Subduction erosion and upper plate deformation induced by the 2014 Mw 8.1 Iquique earthquake
- Author
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Petersen, Florian, Lange, Dietrich, Ma, Bo, Geersen, Jacob, Grevemeyer, Ingo, Klaeschen, Dirk, Contreras-Reyes, Eduardo, Barrientos, Sergio, Tréhu, Anne M., Vera, Emilio, and Kopp, Heidrun
- Abstract
The 2014 Mw 8.1 Iquique earthquake ruptured the boundary between the subducting Nazca Plate and the overriding South American Plate in the North Chilean subduction zone. The broken segment of the South American subduction zone had likely accumulated elastic strain since an M~9 earthquake in 1877 and what therefore considered a mature seismic gap. The moderate magnitude of the 2014 earthquake and its compact rupture area, which only broke the central part of the seismic gap, did not result in a significant tsunami in the Pacific Ocean. To investigate the seismo-tectonic segmentation of the North Chilean subduction zone in the region of the 2014 Iquique earthquake at the shallow seismic/aseismic transition, we combine two years of local aftershock seismicity observations from ocean bottom seismometers and long-offset seismic reflection data from the rupture area. Our study links short term deformation associated with a single seismic cycle to the permanent deformation history of an erosive convergent margin over millions of years. A high density of aftershocks following the 2014 Iquique earthquake occurred in the up-dip region of the coseismic rupture, where they form a trench parallel band. The events spread from the subducting oceanic plate across the plate boundary and into the overriding continental crust. The band of aftershock seismicity separates a pervasively fractured and likely fluid-filled marine forearc farther seaward from a less deformed section of the forearc farther landward. At the transition, active subduction erosion during the postseismic and possibly coseismic phases of the 2014 Iquique earthquake leads to basal abrasion of the upper plate and associated extensional faulting of the overlying marine forearc. Landward migration of the seismogenic up-dip limit, possibly at similar rates compared to the trench and the volcanic arc, leaves behind a heavily fractured and fluid-filled outermost forearc. This most seaward part of the subduction zone might be too weak to store sufficient elastic strain to nucleate a large megathrust earthquake.
- Published
- 2021
15. Seismic reflection character of the plate interface in the rupture zone of the 2014 Iquique earthquake sequence
- Author
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Ma, Bo, Geersen, Jacob, Klaeschen, Dirk, Petersen, Florian, Kopp, Heidrun, Trehu, Anne, and Contreras-Reyes, Eduardo
- Subjects
ddc:550 ,ComputingMethodologies_GENERAL ,FID-GEO-DE-7 - Abstract
poster
- Published
- 2021
16. Seismogenic up-dip limit of the 2014 Mw 8.1 Iquique earthquake links subduction erosion and upper plate deformation
- Author
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Petersen, Florian, Lange, Dietrich, Ma, Bo, Grevemeyer, Ingo, Geersen, Jacob, Klaeschen, Dirk, Contreras-Reyes, Eduardo, Barrientos, Sergio, Tréhu, A. M., Vera, E., and Kopp, Heidrun
- Abstract
The 2014 Mw 8.1 Iquique earthquake ruptured the boundary between the subducting Nazca Plate and the overriding South American Plate in the North Chilean subduction zone. The broken segment of the South American subduction zone had likely accumulated elastic strain since an M~9 earthquake in 1877 and what therefore considered a mature seismic gap. The moderate magnitude of the 2014 earthquake and its compact rupture area, which only broke the central part of the seismic gap, did not result in a significant tsunami in the Pacific Ocean. To investigate the seismo-tectonic segmentation of the North Chilean subduction zone in the region of the 2014 Iquique earthquake at the shallow seismic/aseismic transition, we combine two years of local aftershock seismicity observations from ocean bottom seismometers and long- offset seismic reflection data from the rupture area. Our study links short term deformation associated with a single seismic cycle to the permanent deformation history of an erosive convergent margin over millions of years. A high density of aftershocks following the 2014 Iquique earthquake occurred in the up-dip region of the coseismic rupture, where they form a trench parallel band. The events spread from the subducting oceanic plate across the plate boundary and into the overriding continental crust. The band of aftershock seismicity separates a pervasively fractured and likely fluid-filled marine forearc farther seaward from a less deformed section of the forearc farther landward. At the transition, active subduction erosion during the postseismic and possibly coseismic phases of the 2014 Iquique earthquake leads to basal abrasion of the upper plate and associated extensional faulting of the overlying marine forearc. Landward migration of the seismogenic up-dip limit, possibly at similar rates compared to the trench and the volcanic arc, leaves behind a heavily fractured and fluid-filled outermost forearc. This most seaward part of the subduction zone might be too weak to store sufficient elastic strain to nucleate a large megathrust earthquake.
- Published
- 2021
17. Subduction Erosion and Upper Plate Deformation at the Up-Dip Limit of the 2014 Mw 8.1 Iquique Earthquake
- Author
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Petersen, Florian, Lange, Dietrich, Ma, Bo, Grevemeyer, Ingo, Geersen, Jacob, Kläschen, Dirk, Contreras-Reyes, Eduardo, Barrientos, Sergio, Vera, Emilio, Tréhu, Anne M., and Kopp, Heidrun
- Abstract
The 2014 Mw 8.1 Iquique earthquake ruptured the boundary between the subducting Nazca Plate and the overriding South American Plate in the North Chilean subduction zone. The broken segment of the South American subduction zone had likely accumulated elastic strain since an M~9 earthquake in 1877 and what therefore considered a mature seismic gap. The moderate magnitude of the 2014 earthquake and its compact rupture area, which only broke the central part of the seismic gap, did not result in a significant tsunami in the Pacific Ocean. To investigate the seismo-tectonic segmentation of the North Chilean subduction zone in the region of the 2014 Iquique earthquake at the shallow seismic/aseismic transition, we combine two years of local aftershock seismicity observations from ocean bottom seismometers and long-offset seismic reflection data from the rupture area. Our study links short term deformation associated with a single seismic cycle to the permanent deformation history of an erosive convergent margin over millions of years. A high density of aftershocks following the 2014 Iquique earthquake occurred in the up-dip region of the coseismic rupture, where they form a trench parallel band. The events spread from the subducting oceanic plate across the plate boundary and into the overriding continental crust. The band of aftershock seismicity separates a pervasively fractured and likely fluid-filled marine forearc farther seaward from a less deformed section of the forearc farther landward. At the transition, active subduction erosion during the postseismic and possibly coseismic phases of the 2014 Iquique earthquake leads to basal abrasion of the upper plate and associated extensional faulting of the overlying marine forearc. Landward migration of the seismogenic up-dip limit, possibly at similar rates compared to the trench and the volcanic arc, leaves behind a heavily fractured and fluid-filled outermost forearc. This most seaward part of the subduction zone might be too weak to store sufficient elastic strain to nucleate a large megathrust earthquake.
- Published
- 2021
18. Relationship between subduction erosion and the up‐dip limit of the 2014 Mw 8.1 Iquique earthquake
- Author
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Petersen, Florian, Lange, Dietrich, Ma, Bo, Grevemeyer, Ingo, Geersen, Jacob, Klaeschen, Dirk, Contreras‐Reyes, Eduardo, Barrientos, Sergio, Tréhu, Anne M., Vera, Emilio, Kopp, Heidrun, Petersen, Florian, Lange, Dietrich, Ma, Bo, Grevemeyer, Ingo, Geersen, Jacob, Klaeschen, Dirk, Contreras‐Reyes, Eduardo, Barrientos, Sergio, Tréhu, Anne M., Vera, Emilio, and Kopp, Heidrun
- Abstract
The aftershock distribution of the 2014 Mw 8.1 Iquique earthquake offshore northern Chile, identified from a long‐term deployment of ocean bottom seismometers installed eight months after the mainshock, in conjunction with seismic reflection imaging, provides insights into the processes regulating the up‐dip limit of coseismic rupture propagation. Aftershocks up‐dip of the mainshock hypocenter frequently occur in the upper plate and are associated with normal faults identified from seismic reflection data. We propose that aftershock seismicity near the plate boundary documents subduction erosion that removes mass from the base of the wedge and results in normal faulting in the upper plate. The combination of very little or no sediment accretion and subduction erosion over millions of years has resulted in a very weak and aseismic frontal wedge. Our observations thus link the shallow subduction zone seismicity to subduction erosion processes that control the evolution of the overriding plate. Key Points: - We investigate structure and seismicity at the up-dip end of the 2014 Iquique earthquake rupture using amphibious seismic data. - Seismicity up-dip of the 2014 Iquique earthquake occurs over a broad range likely interpreted to be related to the basal erosion processes. - Coseismic stress changes and aftershocks activate extensional faulting of the upper plate and subduction erosion.
- Published
- 2021
- Full Text
- View/download PDF
19. Microseismicity and lava flows hint at magmato‐tectonic processes near the southern tip of the Fonualei Rift and Spreading Center in the Lau Basin
- Author
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Schmid, Florian, Cremanns, Max, Augustin, Nico, Lange, Dietrich, Petersen, Florian, Kopp, Heidrun, Schmid, Florian, Cremanns, Max, Augustin, Nico, Lange, Dietrich, Petersen, Florian, and Kopp, Heidrun
- Abstract
Spreading centers in the proximity of back‐rolling subduction zones constitute an ideal natural laboratory to investigate the interaction of magmatism and tectonism during the early evolution of back‐arc basins. Using 32 days of ocean bottom seismometer data, we located 697 microeathquakes at the southern Fonualei Rift and Spreading Center (S‐FRSC). The majority of epicenters concentrate along the central region of the axial valley, marking the active ridge axis. Only odd events were associated with the prominent faults bounding the axial valley. About 450 events are spatially clustered around 17°42’S and their waveforms show a pronounced similarity. Most of these events are associated with a 138 hours lasting earthquake swarm. The tectonic structure of the ridge axis in the S‐FRSC resembles a series of left‐stepping en echelon segments, expressed at the seafloor by numerous volcanic ridges. The recorded earthquake swarm is located at the stepover of two en echelon segments suggesting that the earthquake swarm is mainly tectonically driven. The events directly beneath our seismic network indicate a maximum depth of brittle faulting down to about 14 km below the seafloor. This is within the maximum depth range of brittle faulting at ultraslow mid‐ocean ridges. Since the thickness of the brittle lithosphere is mainly controlled by temperature, our results suggest a sub‐axial thermal structure similar to that of ultraslow mid‐ocean ridges of similar opening rates.
- Published
- 2021
- Full Text
- View/download PDF
20. Basin inversion in the Ligurian Sea revealed by local seismicity
- Author
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Thorwart, M., Dannowski, Anke, Grevemeyer, Ingo, Lange, Dietrich, Petersen, Florian, Crawford, W., Paul, A., Thorwart, M., Dannowski, Anke, Grevemeyer, Ingo, Lange, Dietrich, Petersen, Florian, Crawford, W., and Paul, A.
- Abstract
The Alpine orogen and the Apennine system are part of the complex tectonic setting in the Mediterranean Sea caused by the convergence between Africa and Eurasia. Between 30 Ma and 15 Ma the Calabrian subduction retreated in a southeast direction pulling Corsica and Sardinia away from the Eurasian landmass. In this extensional setting, the Ligurian Sea was formed as a back-arc basin. The rifting jumped 15 Ma ago in the Tyrrhenian Sea leaving Corsica and Sardinia in a stable position relative to Eurasia.Within the framework of the AlpArray research initiative a long-term seismological experiment was conducted in the Ligurian Sea to investigatethe lithospheric structure and the seismicity in the Ligurian basin. The passive seismic network consisted of 29 broad-band ocean bottom stations from Germany and France. It was in operation between June 2017 and February 2018.Two seismicity clusters occurred in the centre of the Ligurian Basin. The 18 earthquakes are located in the lower crust and in the upper-most mantle at depths between 10 km and 16 km. Re-location was performed only using picks from the OBS in the centre of the Ligurian Sea to avoidartifacts from the complex 3D velocity structure of the basin. Moho-refractions Pn and Sn have apparent velocities of 8.2 km/s and 4.7 km/s. The low Vp-Vs-ratio of 1.72 indicates a more brittle behaviour of the mantle material. Fault plane solutions were determined for four events using also the data of land stations in southern France, Corsica, Sardinia and northern Italy. The focal mechanisms are thrust faulting. Fault planes strike in a NE-SW direction, coinciding with the alignment of the events and the direction of the basin axis. We interprete the two earthquake clusters related to the inversion of the Ligurian Basin where the basin's centre is under compression and stresses are taken up by reactivated faults in the crust and uppermost mantle. The compressional forces could be caused by the convergence of Africa and Europe.
- Published
- 2021
21. Imaging the crustal structure of the southern plate boundary of the Niuafo’ou microplate, Lau Basin, southwest Pacific, with reflection and refractions seismic data
- Author
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Beniest, Anouk, Dannowski, Anke, Schnabel, M., Schmid, Florian, Werner, Reinhard, Kopp, Heidrun, Riedel, Michael, Heyde, I., Barckhausen, U., Petersen, Florian, Schramm, Bettina, Hannington, Mark D., Beniest, Anouk, Dannowski, Anke, Schnabel, M., Schmid, Florian, Werner, Reinhard, Kopp, Heidrun, Riedel, Michael, Heyde, I., Barckhausen, U., Petersen, Florian, Schramm, Bettina, and Hannington, Mark D.
- Abstract
At the Australian-Pacific plate boundary, the northern Lau Basin is one of the fastest opening back-arc basins on earth. The current configuration of micro-plates, plate boundaries and motions within the northern Lau Basin is quite well understood, but in the southern part of the Lau Basin questions remain about the crustal structure. Here, the Central Lau Spreading Center (CLSC) and the southern tip of the Fonualei Rift and Spreading Center (FRSC) define the diffuse southern boundary of the Niuafo’ou microplate. It remains unclear where the southern plate boundary is located and what kind of boundary it is.We present 1) seismic refraction data of a 200-km long, E-W transect acquired in the transition zone from the eastern side of the CLSC to the southern tip of the FRSC and 2) seismic reflection data of four E-W profiles of varying length, acquired in both the southern part of the Niuafo’ou microplate and the transition in between the CLSC and the FRSC. The seismic data acquisition was accompanied by parametric sediment echosounder, gravimetric and magnetic measurements and was complemented by heat flow probes and dredged samples of the seafloor in the vicinity of the profile.Our travel time tomography reveals a pronounced lateral variation in seismic P-wave velocities from west to east, within the 7-8 km thick back-arc crust. Towards the east, the crust gradually thickens to 13 km of arc crust. The reflection seismic data reveals sediment pockets, varying between 300m to 1000m depth, located on both the thinner back-arc crust and thicker arc crust. In the abyssal regions, faults that cross-cut the basement, but do not reach the surface, are observed on all reflection seismic profiles and are considered inactive today. Towards the west of the profiles, faults reach the surface and are considered active. Rock sampling from this area retrieved predominantly massive aphyric basalts from the back-arc crust in the west. Olivine-rich basalts, andesites, and a broad spect
- Published
- 2021
22. Relationship Between Subduction Erosion and the Up‐Dip Limit of the 2014 Mw 8.1 Iquique Earthquake
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Petersen, Florian, primary, Lange, Dietrich, additional, Ma, Bo, additional, Grevemeyer, Ingo, additional, Geersen, Jacob, additional, Klaeschen, Dirk, additional, Contreras‐Reyes, Eduardo, additional, Barrientos, Sergio, additional, Tréhu, Anne M., additional, Vera, Emilio, additional, and Kopp, Heidrun, additional
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- 2021
- Full Text
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23. Marine forearc structure at the seismogenic up-dip end of the 2014 Iquique Mw 8.1 earthquake
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Petersen, Florian, Lange, Dietrich, Ma, Bo, Geersen, Jacob, Grevemeyer, Ingo, Kopp, Heidrun, Contreras-Reyes, Eduardo, Barrientos, Sergio, Tréhu, Anne M., Petersen, Florian, Lange, Dietrich, Ma, Bo, Geersen, Jacob, Grevemeyer, Ingo, Kopp, Heidrun, Contreras-Reyes, Eduardo, Barrientos, Sergio, and Tréhu, Anne M.
- Abstract
On April 1st, the Mw 8.1 Iquique earthquake ruptured the plate boundary in the North Chilean marine forearc. The earthquake did not cause enough shallow rupture in the updip area to trigger a significant tsunami in the Pacific Ocean. The segment of South American subduction-zone affected by the Iquique earthquake was previously considered a seismic gap, as it last ruptured entirely in 1877 during an M~9 earthquake, with a rupture area possibly extending from south of Arica at 19°S to the north of the Mejillones peninsula at 23°S. The smaller magnitude of the 2014 event and the reduced rupture area that only broke the central part of the seismic gap implies a seismo-tectonic segmentation of the marine forearc. To identify the structure of the marine forearc and the subduction plate interface at the shallow seismic/aseismic transition, we use two years of Ocean Bottom Seismometer (OBS) and permanent onshore seismic data recorded eight months after the Iquique mainshock. The high-resolution aftershocks of the 2014 Mw 8.1 Iquique earthquake from the local OBS network together with a seismic reflection image acquired in 2016 of the marine forearc allows us to discuss the structural control on the up-dip extent of seismic rupture in the North Chilean subduction-zone. Most aftershocks occur updip of a co-seismic shallow slip patch in the marine forearc in the vicinity of a large crustal normal fault. A second area of increased aftershocks at the plate interface coincidence with the crustal-scale normal fault that links to the coastal scarp. The updip limit under the marine forearc further correlates with a highly faulted upper-plate and the subduction of Iquique ridge related topography. Combining the results concerning the 2014 Iquique earthquake with information from the 1995 Antofagasta and 2007 Tocopilla earthquakes, we suggest a uniform structural control of seismic rupture that is uniformly active along the Northern Chile.
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- 2020
24. The FOCUS experiment 2020 (Fiber Optic Cable Use for Seafloor studies of earthquake hazard and deformation)
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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
25. Investigations of the Oligocene-Miocene opening of the Ligurian Basin using refraction seismic data
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Kopp, Heidrun, Dannowski, Anke, Grevemeyer, Ingo, Lange, Dietrich, Thorwart, Martin, Caielli, Grazia, Franco, Roberto, Petersen, Florian, Wolf, Felix Noah, Schramm, Bettina, Kopp, Heidrun, Dannowski, Anke, Grevemeyer, Ingo, Lange, Dietrich, Thorwart, Martin, Caielli, Grazia, Franco, Roberto, Petersen, Florian, Wolf, Felix Noah, and Schramm, Bettina
- Abstract
The Ligurian Basin is located north-west of Corsica at the transition from the western Alpine orogen to the Apennine system. The Back-arc basin was generated by the southeast trench retreat of the Apennines-Calabrian subduction zone. The opening took place from late Oligocene to Miocene. While the extension led to extreme continental thinning and un-roofing of mantle material little is known about the style of back-arc rifting. To shed light on the present day crustal and lithospheric architecture of the Ligurian Basin, active seismic data have been recorded on short period ocean bottom seismometers in the framework of SPP2017 4D-MB, the German component of AlpArray. An amphibious refraction seismic profile was shot across the Ligurian Basin in an E-W direction from the Gulf of Lion to Corsica. The profile extends onshore Corsica to image the necking zone of continental thinning. The majority of the refraction seismic data show mantle phases at offsets up to 70 km. The arrivals of seismic phases were picked and inverted in a travel time tomography. The results show a crust-mantle boundary in the central basin at ~12 km depth below sea surface. The mantle shows rather high velocities >7.8 km/s. The crust-mantle boundary deepens from ~12 km to ~18 km within 25 - 30 km towards Corsica. The results do not map an axial valley as expected for oceanic spreading. However, an extremely thinned continental crust indicates a long lasting rifting process that possibly does not initiated oceanic spreading before the opening of the Ligurian Basin stopped.
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- 2020
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26. Crustal Structure of the Southern Plate Boundary of the Niuafo’ou Microplate, Lau Basin, Southwest Pacific Ocean
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Beniest, Anouk, Dannowski, Anke, Schnabel, Michael, Werner, Reinhard, Kopp, Heidrun, Heyde, Ingo, Barckhausen, Udo, Riedel, Michael, Schmid, Florian, Petersen, Florian, Hannington, Mark D., Beniest, Anouk, Dannowski, Anke, Schnabel, Michael, Werner, Reinhard, Kopp, Heidrun, Heyde, Ingo, Barckhausen, Udo, Riedel, Michael, Schmid, Florian, Petersen, Florian, and Hannington, Mark D.
- Abstract
The northern Lau Basin, at the Australian-Pacific plate boundary, is one of the fastest opening back-arc basins on earth. An amalgamation of active rifts and spreading centers accommodates the extension. The current configuration of micro-plates, motions and plate-boundaries within the northern Lau Basin has been studied, but remains complex. Especially in the southern part of the Lau Basin questions remain about the crustal structure. In this area, the Central Lau Spreading Center (CLSC) and the southern tip of the Fonualei Rift and Spreading Center (FRSC) define the diffuse southern boundary of the Niuafo’ou microplate. It remains unclear where the southern plate boundary is located and what kind of boundary it is. We present seismic refraction and reflection data of a 200-km long transect in the transition zone from the eastern side of the CLSC to the southern tip of the FRSC. The seismic data recording was accompanied by parametric sediment echosounder data, gravimetric and magnetic measurements and dredged samples of the seafloor in the vicinity of the profile. A travel time tomography reveals a pronounced lateral variation in seismic P-wave velocities from west to east, within the 7-8 km thick back-arc-crust. Towards the east the crust gradually thickens to 13 km of arc-crust. The reflection seismic data reveals sediment pockets that vary between 300m to 1000m depth and are located on both the thinner back-arc crust and thicker arc-crust. Rock sampling along the transect retrieved predominantly massive aphyric basalts from the back-arc-crust in the west. Ol-Px-Pl-phyric basalts, andesites, and a broad spectrum of volcaniclastic rocks are the most common rock-type collected from the arc-crust in the east. These rocks are currently analyzed to determine the age and geochemical (major, trace element and Sr-Nd-Pb-Hf isotopic) composition of the sampled structures. The lack of a thinner crust near the southern tip of the FRSC is located and a wide distribution of n
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- 2020
27. Active subduction erosion at the updip end of the 2014 Mw 8.1 Iquique earthquake in North Chile
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Petersen, Florian, Lange, Dietrich, Ma, Bo, Geersen, Jacob, Grevemeyer, Ingo, Klaeschen, Dirk, Conteras-Reyes, Eduardo, Barrientos, Sergio, Tréhu, Anne M., Kopp, Heidrun, Petersen, Florian, Lange, Dietrich, Ma, Bo, Geersen, Jacob, Grevemeyer, Ingo, Klaeschen, Dirk, Conteras-Reyes, Eduardo, Barrientos, Sergio, Tréhu, Anne M., and Kopp, Heidrun
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- 2020
28. Microseismicity indicates a current transition from rifting to spreading at the southern Fonualei Rift and Spreading Center in the Lau Basin
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Schmid, Florian, Cremanns, Maximilian, Augustin, Nico, Lange, Dietrich, Petersen, Florian, Kopp, Heidrun, Schmid, Florian, Cremanns, Maximilian, Augustin, Nico, Lange, Dietrich, Petersen, Florian, and Kopp, Heidrun
- Abstract
Young extension centers in the proximity of back-rolling subduction zones constitute an ideal natural laboratory to investigate the early evolutional stages of back-arc basins. We present a catalog of 711 microearthquakes recorded during a 32-days deployment of ocean bottom seismometers at the southern part of the Fonualei Rift and Spreading Center in the Lau Basin. The majority of epicenters are concentrated along the central region of the axial valley and about 450 events are associated with an earthquake swarm that is likely linked to magmatic diking in the crust. The earthquake swarm location coincides with several volcanic mounds on the seafloor, covered by fresh lava flows. The spatial distribution of microearthquakes and the maximum depth of brittle faulting is more similar to oceanic spreading centers than to continental rift zones. We interpret our results in conjunction with refraction seismic data and magnetic anomaly data from the same region. In combing all findings, we conclude that the southern Fonualei Rift and Spreading Center is currently in transition from a rifting dominated mode of extension to a seafloor spreading dominated mode of extension. This transition may be associated with fundamental changes in the underlying mechanisms of melt generation leading to a diminishing influence of hydrous flux melting and the growing influence of decompression melting at this back-arc extension zone.
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- 2020
29. Investigations of the Oligocene-Miocene opening of the Ligurian Basin using refraction seismic data
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Kopp, Heidrun, primary, Dannowski, Anke, additional, Grevemeyer, Ingo, additional, Lange, Dietrich, additional, Thorwart, Martin, additional, Caielli, Grazia, additional, Franco, Roberto, additional, Petersen, Florian, additional, Wolf, Felix Noah, additional, and Schramm, Bettina, additional
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- 2020
- Full Text
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30. Investigations of the Ligurian Basin using refraction seismic data and the ambient noise technique
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Dannowski, Anke, Wolf, Felix Noah, Kopp, Heidrun, Grevemeyer, Ingo, Lange, Dietrich, Thorwart, Martin, Crawford, Wayne, Caielli, Grazia, de Franco, Roberto, Paul, Anne, Petersen, Florian, and Schramm, Bettina
- Published
- 2019
31. Applying laser reflectometry to study active submarine faults: the FOCUS project (FOCUS = Fiber Optic Cable Use for Seafloor studies of earthquake hazard and deformation)
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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.
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- 2019
32. The structure of the 2014 Mw 8.1 Iquique earthquake revealed by offshore observations
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Petersen, Florian, Lange, Dietrich, Grevemeyer, Ingo, Kopp, Heidrun, Contreras-Reyes, Eduardo, Barrientos, Sergio, and Tréhu, Anne
- Abstract
On April 2014 the Iquique Mw 8.1 earthquake ruptured the interpolate contact between the oceanic Nazca and continental South American plates offshore northern Chile between 19.5◦S to 21◦S in April 2014. This earthquake did not fully release the strain accumulated since the last great megathrust (Mw 8.8) in 1877 and had left an unbroken segment in the south. From December 2014 to November 2016, we deployed an offshore network of 15 Ocean Bottom Seismometers (OBS) that covered the rupture area and the unbroken southern segment using the Chilean Navy ship OPV Toro and R/V Sonne. That data set is supplemented by five weeks of data from 67 OBS installed for a controlled source seismic experiment during cruise MGL1610 of the R/V Marcus Langseth in late 2016. Data acquired onshore by stations from of the IPOC (Integrated Plate Boundary Observatory Chile) and CSN (Chilean Seismological Service) networks are also included. We present first results of this ongoing project, which include double-difference hypocenter relocations based on waveform cross-correlation. Most of the seismicity occurs between 19.5 and 21◦S up-dip of the patch of maximum coseismic slip during the 2014 earthquake, while the seismicity in seismogenic depths is highly concentrated forming well-defined clusters. The observed seismicity provides constraints on the structure of the marine forearc and enables us to relate the seismicity distribution to the background seismicity, seafloor morphology, and regional tectonics.
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- 2019
33. Fiber optic monitoring of active faults at the seafloor: I the FOCUS project
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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.
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- 2019
- Full Text
- View/download PDF
34. Marine forearc structure of the 2014 Mw 8.1 Iquique earthquake revealed by hypocenter locations from offshore observations
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Petersen, Florian, Lange, Dietrich, Grevemeyer, Ingo, Kopp, Heidrun, Contreras-Reyes, Eduardo, Barrientos, S., Trehu, A. M., Petersen, Florian, Lange, Dietrich, Grevemeyer, Ingo, Kopp, Heidrun, Contreras-Reyes, Eduardo, Barrientos, S., and Trehu, A. M.
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- 2019
35. Marine forearc structure of the 2014 Mw 8.1 Iquique earthquake in Northern Chile revealed by relocated hypocenter locations from offshore observations
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Petersen, Florian, Lange, Dietrich, Grevemeyer, Ingo, Kopp, Heidrun, Trehu, A. M., Contreras-Reyes, Eduardo, Barrientos, S., Petersen, Florian, Lange, Dietrich, Grevemeyer, Ingo, Kopp, Heidrun, Trehu, A. M., Contreras-Reyes, Eduardo, and Barrientos, S.
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- 2019
36. Extremely thinned continental crust underneath the Ligurian Basin?
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Dannowski, Anke, Kopp, Heidrun, Grevemeyer, Ingo, Lange, Dietrich, Thorwart, Martin, Crawford, W. C., Caielli, Grazia, de Franco, Robert, Paul, Anne, Wolf, Felix Noah, Petersen, Florian, Schramm, Bettina, Xia, Yueyang, Dannowski, Anke, Kopp, Heidrun, Grevemeyer, Ingo, Lange, Dietrich, Thorwart, Martin, Crawford, W. C., Caielli, Grazia, de Franco, Robert, Paul, Anne, Wolf, Felix Noah, Petersen, Florian, Schramm, Bettina, and Xia, Yueyang
- Abstract
The Ligurian Basin is situated at the transition from the western Alpine orogeny to the Apennine system, an area where a change in subduction polarity is observed. The back-arc basin was generated by the southeast trench retreat of the Apennines-Calabrian subduction zone. The opening took place from late Oligocene to Miocene. While the extension led to continental thinning and subsidence, oceanic spreading with unroofing of mantle material was proposed for the late opening period, 21-16 Ma. To shed light on the present day crustal and lithospheric architecture of the Ligurian Basin, active and passive seismic data have been recorded on ocean bottom seismometers of a long-term network consisting of 29 broad-band stations, installed from June 2017 to February 2018 in the framework of SPP2017 4D-MB, the German component of AlpArray. Two refraction seismic profiles were shot to serve two aspects: (1) Determine the orientation of the horizontal components of the long-term instruments and (2) estimate the velocity distribution of the upper lithosphere, to provide a velocity model for the passive seismic data analysis. Good quality data have been recorded, regional and teleseismic events as well as active shots could be detected by the network stations. The majority of the refraction seismic data show mantle phases at offsets up to 70 km and a very prominent wide-angle reflection originating at the crust mantle boundary. Its features share a number of characteristics (i.e. offset range, continuity) generally associated with continental settings rather than mimicking seafloor spreading lithosphere emplaced in back-arc basins. Based on traveltime tomography along the refraction lines, the crust-mantle boundary is determined at ~9.5 km depth below seafloor. The acoustic basement is difficult to map seismically. The transition to the crystalline basement is indicated at a depth of ~6.5 km below seafloor. The absolute seismic velocities can be interpreted as hyper-extended cont
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- 2019
37. Formation and Rifting of backarc crust in the Lau Basin: First results of a recent seismic experiment
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Schmid, Florian, Dannowski, Anke, Kopp, Heidrun, Petersen, Florian, Schnabel, Michael, Barckhausen, Udo, Schramm, Bettina, Beniest, Anouk, Brandl, Philipp, Weber, Michael, Hannington, M. D., Schmid, Florian, Dannowski, Anke, Kopp, Heidrun, Petersen, Florian, Schnabel, Michael, Barckhausen, Udo, Schramm, Bettina, Beniest, Anouk, Brandl, Philipp, Weber, Michael, and Hannington, M. D.
- Abstract
Several aspects of the formation and rifting of crust in backarc environments, like the Lau Basin in the SW Pacific, are still under question. A major unresolved question is, at what stage in the structural and thermal evolution of arc rifting does magmatism begin? The Fonualei Rift and Spreading Centre in Northeastern Lau Basin separates the Tonga Volcanic Arc from the Lau Backarc Basin and shows a strong gradient in the opening rate from South to North. The rift represents an ideal study site to investigate the formation and rifting of backarc crust at different stages of its tectonic and magmatic evolution. During the multidisciplinary cruise SO267 of RV Sonne (project ARCHIMEDES I), which sailed from Dec. 11, 2018 to Jan. 26, 2019, coincident seismic refraction and reflection profiles were acquired to image the deep crustal structure covering different sections of the Fonualei Rift and Spreading Centre. A total of 50 OBS from the GEOMAR pool were available for the refraction lines. Instruments were spaced at an average distance of 6 km and recorded arrivals from up 120 km offset. Seismic phases show little to no sediment cover on the seabed. Clear mantle arrivals (PmP and Pn) were recorded by the majority of stations and will allow the assessment of crustal thickness and upper mantle velocities. Additional geophysical data included gravity, magnetics and high-resolution bathymetry as well as Parasound and heatflow data, which were acquired along all profiles and will contribute to the tectonic interpretation of this complex region that is characterized by a number of microplates, active and abandoned spreading centres and transfer zones. This contribution will present an overview of the major scientific questions driving the ARCHIMEDES I project and present first results from the acquired seismic profiles, which aim to reveal the crustal architecture and the opening history of the Lau Basin.
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- 2019
38. Measuring tectonic seafloor deformation and strain-build up with acoustic direct-path ranging
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Petersen, Florian, Kopp, Heidrun, Lange, Dietrich, Hannemann, Katrin, Urlaub, Morelia, Petersen, Florian, Kopp, Heidrun, Lange, Dietrich, Hannemann, Katrin, and Urlaub, Morelia
- Abstract
The Earth’s ocean floor deforms continuously under the influence of plate tectonic processes. In recent years, the development of deep-sea instruments using acoustic direct-path ranging allows observations of ocean floor deformation with unprecedented spatial and temporal resolution. Due to rapid technological progress, acoustic ranging emerged as a central research field to monitor seafloor deformation. Here we review recent developments and the progress of direct-path ranging applications. We discuss the methodology and examine the effects of the oceanographic environment on the measurement precision. Comparing the resolution of previous deployments, we find that the baseline uncertainty increases linearly with baseline length, at least for distances up to 3 km, but with different linear relations for each deployment. Measurements of displacement at millimeter-level precision across normal, thrust or strike-slip faults are discussed to evaluate the influence of dedicated network designs appropriate for the discrete fault geometries. Furthermore, tectonically quiet areas, such as flanks of coastal or ocean island volcanoes and passive continental margins pose substantial hazards that often lack in-situ monitoring and are therefore a significant target for the application of seafloor geodetic techniques.
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- 2019
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39. LOBSTER - Ligurian Ocean Bottom Seismology and Tectonics
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Dannowski, Anke, Wolf, Felix Noah, Kopp, Heidrun, Grevemeyer, Ingo, Lange, Dietrich, Thorwart, Martin, Crawford, W., Caielli, G., de Franco, R., Paul, A., Petersen, Florian, Schramm, Bettina, Dannowski, Anke, Wolf, Felix Noah, Kopp, Heidrun, Grevemeyer, Ingo, Lange, Dietrich, Thorwart, Martin, Crawford, W., Caielli, G., de Franco, R., Paul, A., Petersen, Florian, and Schramm, Bettina
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- 2019
40. Investigations of the crust and upper mantle in the Ligurian Basin using refraction seismic data and ambient noise – LOBSTER
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Dannowski, Anke, Wolf, Felix Noah, Kopp, Heidrun, Grevemeyer, Ingo, Lange, Dietrich, Thorwart, Martin, Crawford, W., Caielli, G., de Franco, R., Paul, A., Petersen, Florian, Schramm, Bettina, Dannowski, Anke, Wolf, Felix Noah, Kopp, Heidrun, Grevemeyer, Ingo, Lange, Dietrich, Thorwart, Martin, Crawford, W., Caielli, G., de Franco, R., Paul, A., Petersen, Florian, and Schramm, Bettina
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- 2019
41. Multi-scale offshore monitoring of seafloor and subsurface deformation
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Kopp, Heidrun, Lange, Dietrich, Petersen, Florian, Urlaub, Morelia, Kopp, Heidrun, Lange, Dietrich, Petersen, Florian, and Urlaub, Morelia
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- 2019
42. Seafloor geodesy to monitor deformation offshore Northern Chile (GeoSEA)
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Lange, Dietrich, Kopp, Heidrun, Hannemann, Katrin, Petersen, Florian, Bedford, J, Barrientos, Sergio, Lange, Dietrich, Kopp, Heidrun, Hannemann, Katrin, Petersen, Florian, Bedford, J, and Barrientos, Sergio
- Abstract
Within the last decade, satellite-based geodetic techniques such as GPS or InSAR have increased our knowledge about tectonic plate motions and crustal deformation. However, the electromagnetic waves used by these techniques do not penetrate into water and therefore geodetic information for the offshore domain is sparse. The GeoSEA (Geodetic Earthquake Observatory on the SEAfloor) array uses acoustic ranging techniques between stations on the seafloor for relative positioning. We use data from 23 autonomous acoustic transponders installed in three deployments located on the outer rise and on the marine forearc of the northern Chile subduction zone (~21°S). The networks are located immediately south of the Iquique 2014 Mw 8.1 rupture zone. Stations were deployed in December 2015 and were mostly recording until June 2018. The geodetic networks monitor crustal deformation of the seafloor with the target to quantify interseismic deformation. Although we achieve a mm-scale precision with our acoustic ranging system, we observe no significant deformation above our resolution limits. We compare our observations with surface strain models estimated using onshore cGPS stations of the Plate Boundary Observatory Chile (IPOC). The predicted strains are of a similar order of magnitude compared to the strain resolution of the network. Furthermore, we show pressure data for all three networks. Although the resolution of the pressure sensors is in the cm-range, the data do not reveal any sudden vertical movements of the seafloor, indicating absence of vertical crustal movement.
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- 2019
43. Seismic investigations of the Ligurian Basin
- Author
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Dannowski, Anke, Kopp, Heidrun, Grevemeyer, Ingo, Lange, Dietrich, Thorwart, Martin, Crawford, W., Caielli, G., de Franco, R., Paul, A., Petersen, Florian, Wolf, Felix Noah, Schramm, Bettina, Dannowski, Anke, Kopp, Heidrun, Grevemeyer, Ingo, Lange, Dietrich, Thorwart, Martin, Crawford, W., Caielli, G., de Franco, R., Paul, A., Petersen, Florian, Wolf, Felix Noah, and Schramm, Bettina
- Published
- 2019
44. Gravitational collapse of Mount Etna’s southeastern flank
- Author
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Urlaub, Morelia, Petersen, Florian, Gross, Felix, Bonforte, Alessandro, Puglisi, Giuseppe, Guglielmino, Francesco, Krastel, Sebastian, Lange, Dietrich, and Kopp, Heidrun
- Subjects
Geophysics ,SciAdv r-articles ,Research Articles ,Research Article - Abstract
Gravitational collapse of Mount Etna’s SE flank: New seafloor geodetic data capture active displacement of underwater volcanic flank., The southeastern flank of Etna volcano slides into the Ionian Sea at rates of centimeters per year. The prevailing understanding is that pressurization of the magmatic system, and not gravitational forces, controls flank movement, although this has also been proposed. So far, it has not been possible to separate between these processes, because no data on offshore deformation were available until we conducted the first long-term seafloor displacement monitoring campaign from April 2016 until July 2017. Unprecedented seafloor geodetic data reveal a >4-cm slip along the offshore extension of a fault related to flank kinematics during one 8-day-long event in May 2017, while displacement on land peaked at ~4 cm at the coast. As deformation increases away from the magmatic system, the bulk of Mount Etna’s present continuous deformation must be driven by gravity while being further destabilized by magma dynamics. We cannot exclude flank movement to evolve into catastrophic collapse, implying that Etna’s flank movement poses a much greater hazard than previously thought. The hazard of flank collapse might be underestimated at other coastal and ocean island volcanoes, where the dynamics of submerged flanks are unknown.
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- 2018
45. The AlpArray seismic network
- Author
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Hetenyi, Gyorgy, Molinari, Irene, Clinton, John, Bokelmann, Gotz, Bondar, Istvan, Crawford, Wayne C., Dessa, Jean-Xavier, Doubre, Cecile, Friederich, Wolfgang, Fuchs, Florian, Giardini, Domenico, Graczer, Zoltan, Handy, Mark R., Herak, Marijan, Jia, Yan, Kissling, Edi, Kopp, Heidrun, Korn, Michael, Margheriti, Lucia, Meier, Thomas, Mucciarelli, Marco, Paul, Anne, Pesaresi, Damiano, Piromallo, Claudia, Plenefisch, Thomas, Plomerova, Jaroslava, Ritter, Joachim, Rumpker, Georg, Sipka, Vesna, Spallarossa, Daniele, Thomas, Christine, Tilmann, Frederik (Prof.), Wassermann, Joachim, Weber, Michael (Prof. Dr.), Weber, Zoltan, Wesztergom, Viktor, Zivcic, Mladen, Abreu, Rafael, Allegretti, Ivo, Apoloner, Maria-Theresia, Aubert, Coralie, Besancon, Simon, de Berc, Maxime Bes, Brunel, Didier, Capello, Marco, Carman, Martina, Cavaliere, Adriano, Cheze, Jerome, Chiarabba, Claudio, Cougoulat, Glenn, Cristiano, Luigia, Czifra, Tibor, Danesi, Stefania, Daniel, Romuald, Dannowski, Anke, Dasovic, Iva, Deschamps, Anne, Egdorf, Sven, Fiket, Tomislav, Fischer, Kasper, Funke, Sigward, Govoni, Aladino, Groschl, Gidera, Heimers, Stefan, Heit, Ben, Herak, Davorka, Huber, Johann, Jaric, Dejan, Jedlicka, Petr, Jund, Helene, Klingen, Stefan, Klotz, Bernhard, Kolinsky, Petr, Kotek, Josef, Kuhne, Lothar, Kuk, Kreso, Lange, Dietrich, Loos, Jurgen, Lovati, Sara, Malengros, Deny, Maron, Christophe, Martin, Xavier, Massa, Marco, Mazzarini, Francesco, Metral, Laurent, Moretti, Milena, Munzarova, Helena, Nardi, Anna, Pahor, Jurij, Pequegnat, Catherine, Petersen, Florian, Piccinini, Davide, Pondrelli, Silvia, Prevolnik, Snjezan, Racine, Roman, Regnier, Marc, Reiss, Miriam, Salimbeni, Simone, Santulin, Marco, Scherer, Werner, Schippkus, Sven, Schulte-Kortnack, Detlef, Solarino, Stefano, Spieker, Kathrin, Stipcevic, Josip, Strollo, Angelo, Sule, Balint, Szanyi, Gyongyver, Szucs, Eszter, Thorwart, Martin, Ueding, Stefan, Vallocchia, Massimiliano, Vecsey, Ludek, Voigt, Rene, Weidle, Christian, Weyland, Gauthier, Wiemer, Stefan, Wolf, Felix, Wolyniec, David, and Zieke, Thomas
- Subjects
ddc:550 ,Institut für Geowissenschaften - Abstract
The AlpArray programme is a multinational, European consortium to advance our understanding of orogenesis and its relationship to mantle dynamics, plate reorganizations, surface processes and seismic hazard in the Alps-Apennines-Carpathians-Dinarides orogenic system. The AlpArray Seismic Network has been deployed with contributions from 36 institutions from 11 countries to map physical properties of the lithosphere and asthenosphere in 3D and thus to obtain new, high-resolution geophysical images of structures from the surface down to the base of the mantle transition zone. With over 600 broadband stations operated for 2 years, this seismic experiment is one of the largest simultaneously operated seismological networks in the academic domain, employing hexagonal coverage with station spacing at less than 52 km. This dense and regularly spaced experiment is made possible by the coordinated coeval deployment of temporary stations from numerous national pools, including ocean-bottom seismometers, which were funded by different national agencies. They combine with permanent networks, which also required the cooperation of many different operators. Together these stations ultimately fill coverage gaps. Following a short overview of previous large-scale seismological experiments in the Alpine region, we here present the goals, construction, deployment, characteristics and data management of the AlpArray Seismic Network, which will provide data that is expected to be unprecedented in quality to image the complex Alpine mountains at depth.
- Published
- 2018
46. Monitoring Seafloor Deformation: Acoustic Ranging Geodesy with Millimeter Precision
- Author
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Petersen, Florian, Kopp, Heidrun, Lange, Dietrich, Hannemann, Katrin, and Urlaub, Morelia
- Published
- 2018
47. RV MARIA S. MERIAN Fahrtbericht / Cruise Report MSM71 LOBSTER: Ligurian Ocean Bottom Seismology and Tectonics Research, Las Palmas (Spain) – Heraklion (Greece) 07.02.-27.02.2018
- Author
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Kopp, Heidrun, Lange, Dietrich, Thorwart, Martin, Paul, Anne, Dannowski, Anke, and Petersen, Florian
- Published
- 2018
- Full Text
- View/download PDF
48. The AlpArray Seismic Network: A Large‑Scale European Experiment to Image the Alpine Orogen
- Author
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Hetényi, György, Molinari, Irene, Clinton, John, Bokelmann, Götz, Bondár, István, Crawford, Wayne C., Dessa, Jean-Xavier, Doubre, Cécile, Friederich, Wolfgang, Fuchs, Florian, Giardini, Domenico, Gráczer, Zoltán, Handy, Mark R., Herak, Marijan, Jia, Yan, Kissling, Edi, Kopp, Heidrun, Korn, Michael, Margheriti, Lucia, Meier, Thomas, Mucciarelli, Marco, Paul, Anne, Pesaresi, Damiano, Piromallo, Claudia, Plenefisch, Thomas, Plomerová, Jaroslava, Ritter, Joachim, Rümpker, Georg, Šipka, Vesna, Spallarossa, Daniele, Thomas, Christine, Tilmann, Frederik, Wassermann, Joachim, Weber, Michael, Wéber, Zoltán, Wesztergom, Viktor, Živčić, Mladen, Abreu, Rafael, Allegretti, Ivo, Apoloner, Maria-Theresia, Aubert, Coralie, Besançon, Simon, Bès de Berc, Maxime, Brunel, Didier, Capello, Marco, Čarman, Martina, Cavaliere, Adriano, Chèze, Jérôme, Chiarabba, Claudio, Cougoulat, Glenn, Cristiano, Luigia, Czifra, Tibor, D’Alema, Ezio, Danesi, Stefania, Daniel, Romuald, Dannowski, Anke, Dasović, Iva, Deschamps, Anne, Egdorf, Sven, Fiket, Tomislav, Fischer, Kasper, Funke, Sigward, Govoni, Aladino, Gröschl, Gidera, Heimers, Stefan, Heit, Ben, Herak, Davorka, Huber, Johann, Jarić, Dejan, Jedlička, Petr, Jund, Hélène, Klingen, Stefan, Klotz, Bernhard, Kolínský, Petr, Kotek, Josef, Kühne, Lothar, Kuk, Krešo, Lange, Dietrich, Loos, Jürgen, Lovati, Sara, Malengros, Deny, Maron, Christophe, Martin, Xavier, Massa, Marco, Mazzarini, Francesco, Métral, Laurent, Moretti, Milena, Munzarová, Helena, Nardi, Anna, Pahor, Jurij, Péquegnat, Catherine, Petersen, Florian, Piccinini, Davide, Pondrelli, Silvia, Prevolnik, Snježan, Racine, Roman, Régnier, Marc, Reiss, Miriam, Salimbeni, Simone, Santulin, Marco, Scherer, Werner, Schippkus, Sven, Schulte-Kortnack, Detlef, Solarino, Stefano, Spieker, Kathrin, Stipčević, Josip, Strollo, Angelo, Süle, Bálint, Szanyi, Gyöngyvér, Szűcs, Eszter, Thorwart, Martin, Ueding, Stefan, Vallocchia, Massimiliano, Vecsey, Luděk, Voigt, René, Weidle, Christian, Weyland, Gauthier, Wiemer, Stefan, Wolf, Felix, Wolyniec, David, Zieke, Thomas, Publikationen aller GIPP-unterstützten Projekte, Deutsches GeoForschungsZentrum, Université de Lausanne = University of Lausanne (UNIL), Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology [Zürich] (ETH Zürich), Kövesligethy Radó Seismological Observatory, Institut de Physique du Globe de Paris (IPGP), Institut national des sciences de l'Univers (INSU - CNRS)-Université Paris Diderot - Paris 7 (UPD7)-Université de La Réunion (UR)-Institut de Physique du Globe de Paris (IPG Paris)-Centre National de la Recherche Scientifique (CNRS), Géoazur (GEOAZUR 7329), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de la Côte d'Azur, COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-COMUE Université Côte d'Azur (2015-2019) (COMUE UCA)-Université Côte d'Azur (UCA)-Centre National de la Recherche Scientifique (CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud]), Dynamique globale et déformation active (IPGS) (IPGS-DGDA), Institut de physique du globe de Strasbourg (IPGS), Université de Strasbourg (UNISTRA)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), Department of Mathematics and Computer Science, Freie Universität Berlin, Department of Earth Sciences [Swiss Federal Institute of Technology - ETH Zürich] (D-ERDW), Helmholtz Centre for Ocean Research [Kiel] (GEOMAR), Istituto Nazionale di Geofisica e Vulcanologia - Sezione di Roma (INGV), Istituto Nazionale di Geofisica e Vulcanologia, Christian-Albrechts-Universität zu Kiel (CAU), Istituto Nazionale di Geofisica e di Oceanografia Sperimentale (OGS), Institut des Sciences de la Terre (ISTerre), Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-Institut national des sciences de l'Univers (INSU - CNRS)-Institut de recherche pour le développement [IRD] : UR219-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019]), Bundesanstalt für Geowissenschaften und Rohstoffe (BGR), Goethe-University Frankfurt am Main, Università degli studi di Genova = University of Genoa (UniGe), Ludwig-Maximilians-Universität München (LMU), GeoForschungsZentrum - Helmholtz-Zentrum Potsdam (GFZ), Research Centre for Astronomy and Earth Sciences [Budapest], Hungarian Academy of Sciences (MTA), Slovenian Environment Agency, Swiss National Science Foundation (Grants SINERGIA CRSII2_1544341 and OROG3NY PP00P2_157627), (b) National Research, Development and Innovation Fund, Hungary (Grant NKFI K124241), (c) Hungarian Academy of Sciences (Grants EU-04/2014, EU-07/2015), (d) Czech Academy of Sciences (Grant M100121201), (e) Operational Programme Research, Development and Education (Project CzechGeo/EPOS-Sci, CZ.02.1.01/0.0/0.0/16_013/0001800), (f) CzechGeo/EPOS (large research infrastructure, Grants LM2010008 and LM2015079), (g) Austrian Science Fund FWF (Project Numbers 26391 and 30707), (h) Deutsche Forschungsgemeinschaft DFG (Grants SPP2017 and MerMet 14-94), (i) INGV for committing internal funding, (j) Agence Nationale de la Recherche, France (contract ANR-15-CE31-0015), (k) RESIF National Research Infrastructure (Investissements d’Avenir, France, ANR-AA-EQPX-0040), (l) French Environment and Energy Management Agency (ADEME) for funding the EGS-Alsace project, (m) Labex OSUG@2020 programme (Investissements d’Avenir, France, ANR10 LABX56), (n) Croatian ScienceFoundation (Grant HRZZ IP-2014-09-9666)., ANR-15-CE31-0015,AlpArray-FR,Voir et comprendre les Alpes en 3D, de la croûte au manteau(2015), ANR-10-LABX-0056,OSUG@2020,Innovative strategies for observing and modelling natural systems(2010), Université de Lausanne (UNIL), Centre National de la Recherche Scientifique (CNRS)-Université de La Réunion (UR)-Université Paris Diderot - Paris 7 (UPD7)-IPG PARIS-Institut national des sciences de l'Univers (INSU - CNRS), Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS)-Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS)-Institut national des sciences de l'Univers (INSU - CNRS), Department of Mathematics and Computer Science (Freie Universität Berlin), Universita degli studi di Genova, Eidgenössische Technische Hochschule - Swiss Federal Institute of Technology in Zürich [Zürich] (ETH Zürich), Institut national des sciences de l'Univers (INSU - CNRS)-IPG PARIS-Université Paris Diderot - Paris 7 (UPD7)-Université de La Réunion (UR)-Centre National de la Recherche Scientifique (CNRS), Institut national des sciences de l'Univers (INSU - CNRS)-Institut de Recherche pour le Développement (IRD [France-Sud])-Centre National de la Recherche Scientifique (CNRS)-Observatoire de la Côte d'Azur, Université Côte d'Azur (UCA)-Université Côte d'Azur (UCA), Department of Earth Sciences [ETH Zürich] (D-ERDW), GEOMAR - Helmholtz Centre for Ocean Research [Kiel] (GEOMAR), Université Joseph Fourier - Grenoble 1 (UJF)-Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-Institut national des sciences de l'Univers (INSU - CNRS)-Institut de recherche pour le développement [IRD] : UR219-PRES Université de Grenoble-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA), ANR-15-CE31-0015,AlpArray-FR,Voir et comprendre les Alpes en 3D, de la croûte au manteau, ANR-10-LABX-0056/10-LABX-0056,OSUG@2020,Innovative strategies for observing and modelling natural systems(2010), and Université Grenoble Alpes (UGA)-Centre National de la Recherche Scientifique (CNRS)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-PRES Université de Grenoble-Institut de recherche pour le développement [IRD] : UR219-Institut national des sciences de l'Univers (INSU - CNRS)-Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-Université Joseph Fourier - Grenoble 1 (UJF)
- Subjects
Seismometer ,010504 meteorology & atmospheric sciences ,Geophysical imaging ,[SDU.STU.GP]Sciences of the Universe [physics]/Earth Sciences/Geophysics [physics.geo-ph] ,Seismic imaging ,010502 geochemistry & geophysics ,Seismic network ,Geodynamics ,01 natural sciences ,Article ,seismology ,Alps ,seismic network ,geodynamics ,seismic imaging ,mountain building ,Mountain building ,Seismology ,Geophysics ,Geochemistry and Petrology ,Lithosphere ,Asthenosphere ,Transition zone ,500 Naturwissenschaften und Mathematik::550 Geowissenschaften, Geologie::551 Geologie, Hydrologie, Meteorologie ,ddc:530 ,0105 earth and related environmental sciences ,Physics ,Seismic hazard ,Mountain formation ,Geology - Abstract
The AlpArray programme is a multinational, European consortium to advance our understanding of orogenesis and its relationship to mantle dynamics, plate reorganizations, surface processes and seismic hazard in the Alps–Apennines–Carpathians–Dinarides orogenic system. The AlpArray Seismic Network has been deployed with contributions from 36 institutions from 11 countries to map physical properties of the lithosphere and asthenosphere in 3D and thus to obtain new, high-resolution geophysical images of structures from the surface down to the base of the mantle transition zone. With over 600 broadband stations operated for 2 years, this seismic experiment is one of the largest simultaneously operated seismological networks in the academic domain, employing hexagonal coverage with station spacing at less than 52 km. This dense and regularly spaced experiment is made possible by the coordinated coeval deployment of temporary stations from numerous national pools, including ocean-bottom seismometers, which were funded by different national agencies. They combine with permanent networks, which also required the cooperation of many different operators. Together these stations ultimately fill coverage gaps. Following a short overview of previous large-scale seismological experiments in the Alpine region, we here present the goals, construction, deployment, characteristics and data management of the AlpArray Seismic Network, which will provide data that is expected to be unprecedented in quality to image the complex Alpine mountains at depth., Surveys in Geophysics, 39 (5), ISSN:0169-3298, ISSN:1573-0956
- Published
- 2018
49. Large displacement of Mount Etna’s submerged south-eastern flank: evidence from seafloor geodetic monitoring
- Author
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Urlaub, Morelia, Petersen, Florian, Gross, Felix, Bonforte, Alessandro, Guglielmino, Francesco, Puglisi, Giuseppe, Krastel, Sebastian, Lange, Dietrich, and Kopp, Heidrun
- Published
- 2018
50. Benefitting from cabled observatories to study active submarine faults: the FOCUS project (FOCUS = Fiber Optic Cable Use for Seafloor studies of earthquake hazard and deformation)
- Author
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Gutscher, Marc-Andre, Royer, Jean-Yves, Graindorge, David, Murphy, Shane, Klingelhöfer, Frauke, Cattaneo, Antonio, Barreca, Giovanni, Quetel, Lionel, Riccobene, Georgio, Petersen, Florian, Urlaub, Morelia, Krastel, Sebastian, Gross, Felix, and Kopp, Heidrun
- Published
- 2018
Catalog
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