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  • 1
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    The Langeland Fault System unravelled: Quaternary fault reactivation along an elevated basement block between the North German and Norwegian–Danish basins (2023)
    Details
    Publication Date: 2024-01-24
    Description: 〈p xmlns:mml="http://www.w3.org/1998/Math/MathML" xml:lang="en"〉The reactivation of faults and possible impact on barrier integrity marks a critical aspect for investigations on subsurface usage capabilities. Glacial isostatic adjustments, originating from repeated Quaternary glaciations of northern Europe, cause tectonic stresses on pre‐existing fault systems and structural elements of the North German and Norwegian–Danish basins. Notably, our current understanding of the dynamics and scales of glacially induced fault reactivation is rather limited. A high‐resolution 2D seismic data set recently acquired offshore northeastern Langeland Island allows the investigation of a fault and graben system termed the Langeland Fault System. Seismo‐stratigraphic interpretation of reflection seismic data in combination with diffraction imaging unravels the spatial character of the Langeland Fault System along an elevated basement block of the Ringkøbing–Fyn High. In combination with sediment echosounder data, the data set helps to visualize the continuation of deep‐rooted faults up to the sea floor. Initial Mesozoic faulting occurred during the Triassic. Late Cretaceous inversion reactivated a basement fault flanking the southern border of the elevated basement block of the Ringkøbing–Fyn High while inversion is absent in the Langeland Fault System. Here, normal faulting occurred in the Maastrichtian–Danian. We show that a glacial or postglacial fault reactivation occurred within the Langeland Fault System, as evident by the propagation of the faults from the deeper subsurface up to the sea floor, dissecting glacial and postglacial successions. Our findings suggest that the Langeland Fault System was reactivated over a length scale of a minimum of 8.5 km. We discuss the causes for this Quaternary fault reactivations in the context of glacially induced faulting and the present‐day stress field. The combination of imaging techniques with different penetration depths and vertical resolution used in this study is rarely realized in the hinterland. It can therefore be speculated that many more inherited, deep‐rooted faults were reactivated in Pleistocene glaciated regions.〈/p〉
    Description: Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659
    Description: https://doi.org/10.1594/PANGAEA.954017
    Keywords: ddc:551.8 ; Langeland Fault System ; Quaternary ; fault reactivation ; seismo-stratigraphic interpretation
    Language: English
    Type: doc-type:article
    Location Call Number Limitation Availability
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    CITATION GEO-LEO
  • 2
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    The Paleozoic Hydrocarbon System in the Gotland Basin (Central Baltic Sea) Leaks (2023)
    Details
    Publication Date: 2023-11-16
    Description: 〈title xmlns:mml="http://www.w3.org/1998/Math/MathML"〉Abstract〈/title〉〈p xmlns:mml="http://www.w3.org/1998/Math/MathML" xml:lang="en"〉The Baltic Basin is known for its numerous Paleozoic hydrocarbon reservoirs. There is published evidence that hydrocarbons are leaking from the seafloor, however, little is known about the hydrocarbon migration pathways from Paleozoic source and reservoir rocks toward the seafloor and their escape structures. To investigate these processes, we utilize a new set of multibeam, parametric sediment sub‐bottom profiler and 2D seismic reflection data. The integrated analysis of seismic profiles, diffraction imaging and bathymetric maps allow to identify a hydrocarbon migration system within Silurian and Devonian strata that consists of layer parallel and updip migration beneath sealing layers, migration across seals along faults, and seafloor escape structures in form of elongated depressions. The general migration trend is directed updip, from the Paleozoic reservoirs below the southeastern Baltic Sea toward the Gotland Depression in the northwest. The locations of the hydrocarbon escape structures at the seafloor and their elongated shape are mainly controlled by the regional geological setting of outcropping Paleozoic layers. In addition, iceberg scouring may have facilitated hydrocarbon migration through the Quaternary deposits. The description of this hydrocarbon migration system fills the gap between the known reservoirs and the observed hydrocarbon accumulations and seepages. With regard to potential Carbon Capture and Storage projects, the identification of this hydrocarbon migration system is of great importance, as potential storage sites may be leaking.〈/p〉
    Description: Plain Language Summary: The Baltic Basin including the Baltic Sea is well known for its hydrocarbon reservoirs with ongoing oil production since the 1940s. While there is some published evidence that hydrocarbons are leaking from the seafloor, little is known about the pathways from the reservoirs toward theses leakages. In this study, we use three imaging techniques for the seafloor, the uppermost sediments and the first few kilometers of the subsurface to image the hydrocarbon migration pathways and their escape structures. We find that hydrocarbons are migrating along dipped geological layers from the reservoirs in the southeast toward the Gotland Deep in the northwest. Additionally, we also observe that hydrocarbons are penetrating through these geological layers at locations of pre‐existing small‐scale fractures. The locations, at which the hydrocarbons escape from the seafloor, are mainly controlled by the regional tectonic setting. In addition, iceberg scouring may have had an influence on the exact escape locations. With our findings in this study, we fill the gap between the known reservoirs and the observed seepages and can contribute to questions regarding the potential storage of CO〈sub〉2〈/sub〉 in the Baltic Basin.〈/p〉
    Description: Key Points: 〈list list-type="bullet"〉 〈list-item〉 〈p xml:lang="en"〉Numerous elongated fluid escape depressions are observed at the eastern margin of the Gotland Deep, central Baltic Sea〈/p〉〈/list-item〉 〈list-item〉 〈p xml:lang="en"〉First evidence for fluid migration pathways from Paleozoic toward Quaternary strata in the region〈/p〉〈/list-item〉 〈list-item〉 〈p xml:lang="en"〉Locations of fluid escape is controlled by the regional tectonic setting〈/p〉〈/list-item〉 〈/list〉 〈/p〉
    Description: Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659
    Description: https://doi.org/10.1594/PANGAEA.957436
    Description: https://doi.org/10.1594/PANGAEA.956740
    Description: https://doi.org/10.1594/PANGAEA.957422
    Keywords: ddc:622.1 ; seismic interpretation ; diffraction imaging ; Baltic Sea ; fluid migration pathways ; pockmarks ; carbon capture and storage
    Language: English
    Type: doc-type:article
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    CITATION GEO-LEO
  • 3
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    Time-migrated multichannel seismic data and separated diffraction energy, sediment echosounder data and calculated grids from the Langeland Fault System, Baltic Sea (2023)
    PANGAEA
    Details
    Publication Date: 2024-04-20
    Description: The understanding of the dynamics and scales of glacially induced faulting greatly benefits from an analyis using multiple geophysical datasets. By using a combination of high-resolution 2D seismic reflection data in combination with diffraction imaging, sediment echosounder data and shallow wells, we investigate a fault and graben system offshore Langeland Island in the Baltic Sea, which we term the Langeland Fault System. This approach allows to unravel the spatial character of the Langeland Fault System along an elevated basement block of the Ringkoebing-Fyn High. Our analysis shows the continuation of deep-rooted faults up to the seafloor. Imaging the shallowmost strata reveals Quaternary fault reactivation during glacial or postglacial times. This combination of imaging techniques is rarley realized in the onshore hinterland, thus, representing a unique analysis of Quaternary fault reactivation by combining onshore and offshore data and methods. Seismic data was acquired in September 2020 during a student field exercise cruise onboard R/V Alkor. The survey was organized by the University of Hamburg (Cruise AL545). Seismic data acquisition was carried out using a Mini-GI gun (true GI-mode with a 15 in³ generator and 30 in³ injector volume) and a 48-channel streamer with 4 m group spacing. The data have a dominant frequency of 250 Hz. Signal penetration is up to 1 s two-way travel time (TWT). The seismic processing routine included frequency filtering, amplitude recovery, noise reduction, surface-related multiple attenuation (SRME), Kirchhoff time migration. Innomars SES 2000 parametric sub-bottom profiler, which is hull-mounted on R/V Alkor, was used for the acquistion of the sediment echosounder data (Primary frequencies of about 100 kHz, secondary parametric frequency: 8 kHz). The diffraction imaging is based on separating the dominant reflected wavefield through a coherent summation scheme guided by a dip-based wavefront filter. In a next step, the reflection-only data is subtracted from the input data. The diffraction-only data is then focused using FD migration. By calculating the squared envelope of the focused diffractions, the diffraction energy stacks are obtained. The mapping procedure includes gridding using all available profiles in order to create time-structure maps by minimum curvature spline interpolation. Isochron maps (vertical thickness in two-way time) for the Triassic to Quaternary units were calculated by subtracting the top and bottom horizons of the specific units.
    Keywords: AL545; AL545_5-2_26; AL545_5-2_40; AL545_5-2_41; Alkor (1990); Baltic Sea; Binary Object; Binary Object (File Size); Diffraction imaging; Event label; File content; Glacially induced faults; GPF 19-1_80; Langeland; P26; P40; P41; reflection seismics; sediment echosounder; Seismic; Seismic reflection profile; SEISREFL; thickness maps; time-structure maps
    Type: Dataset
    Format: text/tab-separated-values, 24 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 4
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    2D multichannel seismic reflection processed data (GI Gun working area dataset) of RV METEOR during cruise M177, Gotland Basin, Baltic Sea (2023)
    PANGAEA
    Details
    Publication Date: 2024-04-20
    Description: The Baltic Basin is known for its numerous Paleozoic hydrocarbon reservoirs. There is published evidence that hydrocarbons are leaking from the seafloor, however, little is known about the hydrocarbon migration pathways from Paleozoic source and reservoir rocks towards the seafloor and the escape structures. To investigate the processes involving the fluid migration pathways, we utilized 2D seismic reflection data from the eastern margin of the Gotland Deep. The data was acquired during the 2021 M177 Meteor expedition led by the University of Hamburg. Data acquisition was carried out using two GI guns (true GI-mode with 45 in3 generator and 105 in3 injector volume) and a 144-channel digital streamer with a channel spacing of 6.25 m and an active length of 600 m. Due to technical difficulties, only 72 channels - distributed over the whole streamer length – could be used for processing. Seismic data processing was divided into pre-processing, multiple attenuation and post-stack processing. Pre-processing consisted of geometry-setup (UTM zone 33N), filtering, despiking and spherical gaining. For multiple attenuation, we applied a predictive deconvolution in the τ-p domain, surface related multiple attenuation (SRME) and an f-k filtering attenuation scheme based on move-out differences between primary and multiple reflections. In between these steps we performed several iterations of manual velocity analysis. The post-stack processing included time migration, white noise suppression (4D-DEC), time-variant filtering and RMS scaling. The dominant frequency of the data is about 100 Hz and the vertical resolution of the final seismic images calculated with a velocity of 2000 m/s is about 5 m. The data is stored in SEGY-format with CMP No in header bytes 21-24, CMP x-coordinates in byte header 181-184 and CMP y-coordinates in byte header 185-188.
    Keywords: Baltic Sea; Binary Object; Binary Object (File Size); Binary Object (Media Type); Carbon capture and storage; Comment; DATE/TIME; Diffraction imaging; fluid flow; LATITUDE; LONGITUDE; M177; M177_5-1; Meteor (1986); PaGoDe, GPF 21‐2_040; pockmarks; SEIS; Seismic; seismic interpretation; Start of data file recording, date/time; Start of data file recording, latitude; Start of data file recording, longitude; Stop of data file recording, date/time; Stop of data file recording, latitude; Stop of data file recording, longitude
    Type: Dataset
    Format: text/tab-separated-values, 16 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 5
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    2D seismic reflection data from POSEIDON cruise POS538, offshore Santorini (2023)
    PANGAEA
    Details
    Publication Date: 2024-04-20
    Description: During research cruise POS538, 2D seismic reflection data were collected onboard research vessel FS POSEIDON in November 2019. The profiles cover the Santorini caldera and the neighboring basins around Santorini. Some profiles were used as side survey data for IODP expedition 398 and will only be available after the IODP embargo period. The dataset consists of SEGY files with UTM coordinates stored in bytes 73 and 77 and shot points stored in byte 5. The coordinate system is UTM35 WGS84. Multi-channel seismic data of cruise POS538 were acquired with a high lateral resolution (CMP spacing of ~1.56 m). As a seismic source, we used a GI-pulser that was operated in harmonic mode with primary and secondary volumes of 45 in3. Seismic energy was recorded by multiple concatenated Geometrics GeoEel streamer segments, resulting in active streamer sections ranging from 190 m to 250 m in length. Processing comprised trace-editing, simple frequency filtering (15-1500 Hz), and multiple suppression by means of surface-related multiple elimination (SRME). This was followed by spherical divergence correction, time-variant frequency filtering, pre-stack time migration, top-muting, and white-noise removal. With a main frequency of 125 Hz, the vertical resolution can be approximated to approx. 4-8 m. For more information, see the cruise report (doi:10.3289/cr_pos538).
    Keywords: Aegean Sea; Binary Object; Binary Object (File Size); Common Midpoint; Event label; Latitude of event; Latitude of event 2; Longitude of event; Longitude of event 2; MCSEIS; Multichannel seismics; POS538; POS538_11-1_P5001; POS538_11-1_P5002; POS538_11-1_P5003; POS538_11-1_P5004; POS538_11-1_P5005; POS538_11-1_P5006-01; POS538_11-1_P5006-02; POS538_11-1_P5007; POS538_11-1_P5008; POS538_11-1_P5009; POS538_11-1_P5010; POS538_11-1_P5011; POS538_11-1_P5012; POS538_11-1_P5013; POS538_11-1_P5014; POS538_11-1_P5015; POS538_11-1_P5016; POS538_11-1_P5017; POS538_11-1_P5018; POS538_11-1_P5019; POS538_11-1_P5020-01; POS538_11-1_P5020-02; POS538_11-1_P5021; POS538_20-1_P6001; POS538_20-1_P6002; POS538_20-1_P6003; POS538_20-1_P6004; POS538_20-1_P6005; POS538_20-1_P6006; POS538_2-1_P1001; POS538_2-1_P1002; POS538_2-1_P1003; POS538_2-1_P1004; POS538_2-1_P1005; POS538_2-1_P1006-01; POS538_2-1_P1006-02; POS538_2-1_P1007; POS538_2-1_P1008; POS538_2-1_P1009; POS538_2-1_P2001; POS538_2-1_P2002; POS538_9-1_P3001; POS538_9-1_P3002; POS538_9-1_P3003; POS538_9-1_P3004; POS538_9-1_P3005; POS538_9-1_P3006; POS538_9-1_P3007; Poseidon; Profile; THESEUS; UTM Easting, Universal Transverse Mercator; UTM Northing, Universal Transverse Mercator; UTM Zone, Universal Transverse Mercator
    Type: Dataset
    Format: text/tab-separated-values, 432 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 6
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    Multibeam bathymetry processed data (Kongsberg EM710 working area dataset) of RV METEOR during cruise M177, Gotland Basin, Baltic Sea (2023)
    PANGAEA
    Details
    Publication Date: 2024-04-20
    Description: The Baltic Basin is known for its numerous Paleozoic hydrocarbon reservoirs. There is published evidence that hydrocarbons are leaking from the seafloor, however, little is known about the hydrocarbon migration pathways from Paleozoic source and reservoir rocks towards the seafloor and the escape structures. To investigate the processes related to fluid escape at the seafloor, we utilized a bathymetric map from the eastern margin of the Gotland Deep. The data was acquired during the 2021 M177 Meteor expedition led by the University of Hamburg. Data acquisition was carried out using the hull-mounted SIMRAD EM710 multibeam swath sounder system, which operates in a frequency range between 70 and 100 kHz. The data was calibrated with the water velocity by using two sound velocity measurements. Data processing included manual removal of data errors and gridding with a grid size of 5 x 5 m. Due to bad weather during the acquisition and the resulting ship movements, some errors and artifacts (e.g. periodic wobbling) remained in the data even after intensive processing. The grids are available in UTM coordinates (UTM zone 34N).
    Keywords: Baltic Sea; Bathymetry; Binary Object; Binary Object (File Size); Binary Object (Media Type); Carbon capture and storage; Elevation, maximum; Elevation, minimum; EM710; EM710 multibeam echosounder; File content; fluid flow; Horizontal datum; Horizontal datum, projection stored in file; Latitude, northbound; Latitude, southbound; Longitude, eastbound; Longitude, westbound; M177; M177_0_Underway-2; Meteor (1986); Multibeam Echosounder; Number of depth soundings; PaGoDe, GPF 21‐2_040; pockmarks; Raster cell size; UTM Easting, Universal Transverse Mercator; UTM Northing, Universal Transverse Mercator; UTM Zone, Universal Transverse Mercator
    Type: Dataset
    Format: text/tab-separated-values, 25 data points
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    DATA PANGAEA
  • 7
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    Sediment echosounder processed data (Atlas Parasound P70 working area dataset) of RV METEOR during cruise M177, Gotland Basin, Baltic Sea (2023)
    PANGAEA
    Details
    Publication Date: 2024-04-20
    Description: The Baltic Basin is known for its numerous Paleozoic hydrocarbon reservoirs. There is published evidence that hydrocarbons are leaking from the seafloor, however, little is known about the hydrocarbon migration pathways from Paleozoic source and reservoir rocks towards the seafloor and the escape structures. To investigate the processes involving fluid migration in shallow depths and seafloor fluid escape, we utilized sub-bottom profiler data from the eastern margin of the Gotland Deep. The data was acquired during the 2021 M177 Meteor expedition led by the University of Hamburg. Data acquisition was carried out using the hull-mounted transducer of the PARASOUND system that emits a 4 kHz signal penetrating the first several tens of meters below the seafloor. The data was digitized and stored in SEG-Y format (FFID in byte header 9-12, shot x-coordinate in byte header 73-76 and shot y-coordinate in byte header 77-80). Processing included geometry setup (UTM zone 33N) and bandpass filtering.
    Keywords: Baltic Sea; Binary Object; Binary Object (File Size); Binary Object (Media Type); Carbon capture and storage; Comment; DATE/TIME; fluid flow; LATITUDE; LONGITUDE; M177; M177_0_Underway-1; Meteor (1986); PaGoDe, GPF 21‐2_040; ParaSound; pockmarks; PS; Start of data file recording, date/time; Start of data file recording, latitude; Start of data file recording, longitude; Stop of data file recording, date/time; Stop of data file recording, latitude; Stop of data file recording, longitude; sub-bottom profiles
    Type: Dataset
    Format: text/tab-separated-values, 24 data points
    Location Call Number Limitation Availability
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    DATA PANGAEA
  • 8
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    R/V Poseidon Cruise Report 538 - THESEUS Tsunami hazard of explosive submarine eruptions, 7th October – 28th October 2019, Cartagena (Spain) - Heraklion (Greece) (2020)
    GEOMAR Helmholtz Centre for Ocean Research
    In:  GEOMAR Helmholtz Centre for Ocean Research, Kiel, Germany, 106 pp.
    Details
    Publication Date: 2020-04-23
    Type: Report , NonPeerReviewed
    Format: text
    DOI: 10.3289/cr_pos538
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    OceanRep: Report - Cruise Report
  • 9
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    Structural evolution and disintegration of oceanic intraplate volcanoes: The Bathymetrists Seamounts and its relation to Sierra Leona Rise (eastern equatorial Atlantic) - Cruise No. M152/2, 03.01. – 12.02.2019, Las Palmas (Spain) – Walvis Bay (Namibia), SEDIS (2019)
    Gutachterpanel Forschungsschiffe
    In:  METEOR-Berichte, M152/2 . Gutachterpanel Forschungsschiffe, Bonn, 60 pp.
    Details
    Publication Date: 2019-09-26
    Description: Summary The Bathymetrists Seamounts (BSM) are located north of the volcanic Sierra Leone Rise in the eastern Atlantic between 6° and 9°N. The three W-E, N-S and NE-SW striking directions of the seamounts indicate a clear structural control for the emplacement of these volcanoes. The origin of the melts, their relationship to the Sierra Leone Rise and the role of the faults in the formation of the melts are unknown as the BSM could be explained by plume related volcanism or decompression melting beneath deep (transform) faults. The SEDIS-cruise M152/2 of RV METEOR strove for a better understanding of the life cycle of submarine volcanoes and their effect on the oceanic lithosphere in the oceanic intraplate setting of the BSM and the relationship to the Sierra Leone Rise. The aims were: 1) to understand the interaction between crustal thickness, tectonics and volcanic phases, 2) to investigate the structural, chronological and petrological evolution of individual seamounts and seamount chains, 3) to review slope failures and resulting mass flow processes. We addressed these objectives by more than 4000 km highresolution reflection seismic and more than 5000 km of parametric echosounder, multi-beam, and gravity and magnetic profiles. Rock samples for ground truthing and geochemical research have been collected during 14 dredge stations. We further determined the concentrations in surface seawater and air and the state of air-sea exchange of a number of nowadays globally banned pesticides, polychlorinated biphenyls, brominated flame retardants, polycyclic aromatic hydrocarbons and their derivatives. Zusammenfassung Die Bathymetrists Seeberge liegen nördlich der Sierra Leone Schwelle, einer vulkanischen Plattform im östlichen Atlantik zwischen 6° und 9° N. Diese submarinen Vulkane gruppieren sich entlang W-E, N-S und NE-SW Trends, was eine strukturelle Kontrolle der Vulkanentstehung indiziert. Die Schmelzentstehung sind unbekannt und können mit PlumeVulkanismus oder Dekompressionsschmelzen unter bisher nicht untersuchten Störungen und tiefen Transformstörungen zusammenhängen. Der Bezug zur Sierra Leone Schwelle ist ebenfalls unbekannt. Im Zuge der SEDIS-Expedition M152/2 mit FS METEOR wurde der Lebenszyklus von Unterwasservulkanen und deren geochemischen Einfluss auf die ozeanische Lithosphäre der Bathymetrists Seeberge untersucht. Anhand der profilhaften geophysikalischer Messungen und Dredge-Proben wollen wir 1) die Wechselwirkung zwischen Krustenmächtigkeit, Tektonik und Vulkanismus verstehen, 2) die strukturelle, chronologische und petrologische Entwicklung von Vulkanen und Vulkanketten untersuchen, und 3) Auslösemechanismen, Transportprozesse und Volumina von Hangrutschungen studieren. Zur Bearbeitung der wissenschaftlichen Fragen sammelten wir mehr als 4000 km mehrkanal-reflexionsseismischer und mehr als 5000 km parametrische Sedimentecholot, Fächerlot, Schwere und Magnetik-Profile. Für die geochemischen Arbeiten sammelten wir an 14 Stationen Gesteinsproben unter Einsatz einer Dredge. Die regelmäßige Beprobung der Luft und des Oberflächenwassers diente der Bestimmung der Konzentration von heute weltweit verbotenen Pestiziden, polychlorierten Biphenylen, bromierten Flammschutzmitteln, polyzyklischen aromatischen Kohlenwasserstoffen und deren Derivaten und um den Austausch zwischen Luft und Meer weiter zu verstehen.
    Type: Report , NonPeerReviewed
    Format: text
    DOI: 10.2312/cr_m152_2
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    OceanRep: Report - Cruise Report
  • 10
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    Spatio-temporal evolution of the Kolumbo Volcanic Chain and its link to the volcanic plumbing system of Santorini (2022)
    AGU (American Geophysical Union) | Wiley
    Details
    Publication Date: 2023-11-20
    Description: Key Points High-resolution reflection seismic data reveals that the internal architecture of the Kolumbo Volcanic Chain The Kolumbo Volcanic Chain evolved during two episodes along NE-SW striking normal faults A prominent volcanic ridge connects the Kolumbo Volcanic Chain with Santorini highlighting a former connection between both systems Abstract The Christiana-Santorini-Kolumbo volcanic field in the southern Aegean Sea is one of the most hazardous volcanic regions in the world. Forming the northeastern part of this volcanic field, the Kolumbo Volcanic Chain (KVC) comprises more than submarine volcanic cones. However, due to their inaccessibility, little is known about the spatio-temporal evolution and tectonic control of these submarine volcanoes and their link to the volcanic plumbing system of Santorini. In this study, we use multichannel reflection seismic imaging to study the internal architecture of the KVC and its link to Santorini. We show that the KVC evolved during two episodes, which initiated at ~1 Ma with the formation of mainly effusive volcanic edifices along a NE-SW trending zone. The cones of the second episode were formed mainly by submarine explosive eruptions between 0.7 and 0.3 Ma and partly developed on top of volcanic edifices from the first episode. We identify two prominent normal faults that underlie and continue the two main trends of the KVC, indicating a direct link between tectonics and volcanism. In addition, we reveal several buried volcanic centers and a distinct volcanic ridge connecting the KVC with Santorini, suggesting a connection between the two volcanic centers in the past. This connection was interrupted by a major tectonic event and, as a result, the two volcanic systems now have separate, largely independent plumbing systems despite their proximity
    Type: Article , NonPeerReviewed , info:eu-repo/semantics/article
    Format: text
    Format: text
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    OceanRep: Article in a Scientific Journal - without review
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