GLORIA — GEOMAR Library Ocean Research Information Access

1

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Submarine Landslides on Continental Margins (2003)

Mienert, Jürgen ; Berndt, Christian ; Laberg, J. S. ; [et al.]

Springer

In: In: Ocean Margin Systems. , ed. by Wefer, G., Billet, D., Hebbeln, D., Jorgensen, B. B., Schlüter, M. and van Veering, T. Springer, Berlin, Germany, pp. 179-193. ISBN 3-540-43921-8

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Publication Date: 2018-01-19

Type: Book chapter , NonPeerReviewed

Format: text

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2

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Gas hydrate dissociation and seafloor collapse in the wake of the Storegga Slide, Norway (2005)

Berndt, Christian ; Mienert, Jürgen ; Vanneste, Maarten ; [et al.]

Elsevier

In: In: Onshore-offshore relationships on the North Atlantic Margin. , ed. by Wandås, B. T. G., Eide, E., Gradstein, F. and Nystuen, J. P. Norwegian Petroleum Society (NPF) Special Publication, 12 . Elsevier, Amsterdam, pp. 285-292. ISBN 978-0444518491

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Publication Date: 2018-01-10

Type: Book chapter , NonPeerReviewed

Format: text

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3

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Polygonal fault systems on the mid-Norwegian margin: A long term source for fluid flow (2003)

Berndt, Christian ; Bünz, Stefan ; Mienert, Jürgen

Geological Society

In: In: Subsurface Sediment Mobilization. , ed. by van Rensbergen, P., Hillis, R. R., Maltman, A. J. and Morley, C. K. Geological Society London Special Publications, 216 . Geological Society, London, pp. 283-290. ISBN 1-86239-141-6

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Publication Date: 2020-08-04

Type: Book chapter , PeerReviewed

Format: text

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4

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Gas hydrate in the Arctic and northern North Atlantic oceans (2000)

Max, Michael D. ; Mienert, Jürgen ; Andreassen, K. ; [et al.]

Kluwer

In: In: Natural Gas Hydrate in Oceanic and Permafrost Environments. , ed. by Max, M. D. Coastal Systems and Continental Margins, 5 . Kluwer, Amsterdam, pp. 171-182. ISBN 0-7923-6606-9

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Publication Date: 2018-01-10

Type: Book chapter , NonPeerReviewed

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5

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Geological controls on the gas hydrate system of Formosa Ridge, South China Sea (2014)

Berndt, Christian ; Crutchley, Gareth ; Klaucke, Ingo ; [et al.]

IEEE

In: In: OCEANS 2014 - TAIPEI. IEEE, Taipei, pp. 1-4. ISBN 978-1-4799-3645-8

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Publication Date: 2017-05-29

Description: Formosa Ridge is one of many topographic ridges created by canyon incision into the eastern South China Sea margin. The northwestern termination of the ridge is caused by beheading of the ridge due to a westward shift of the canyon that originally formed to the eastern flank of Formosa Ridge. Below Formosa Ridge a bottom simulating reflector (BSR) exists. Its depth below sea floor coincides with the theoretical base of the gas hydrate stability zone and the reflection has reverse polarity suggesting that it is caused by free gas below gas hydrate accumulations. The BSR is ubiquitous but shows significant variations in depth below sea floor ranging from 150 ms TWT (or approximately 180 m) underneath the incised canyon in the north to up to 500 ms (or approximately 460 m) underneath the crest of Formosa Ridge. Predominantly this depth variation is the result of topography on subsurface temperature, but comparison with the average BSR depth underneath the surrounding canyons suggests that recent canyon incision in the north has perturbed the thermal state of the sediments. Formosa Ridge consists of a northern half that is dominated by refilled older canyons and a southern half that consists mainly of contourite deposits. However, judging by the reflection seismic data this difference in origin seems to have little effect on the distribution of gas hydrate.

Type: Book chapter , NonPeerReviewed

Format: text

DOI: 10.1109/OCEANS-TAIPEI.2014.6964481

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6

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Deep-seated focused fluid migration as indicator for hydrocarbon leads in the East Shetland Platform, North Sea Province (2019)

Karstens, Jens ; Müller, P. ; Berndt, Christian ; [et al.]

Geological Society

In: In: Cross border themes in petroleum geology I: The North Sea. , ed. by Patruno, S., Archer, S. G., Chiarella, D., Howell, J. A., Jackson, C. A. L. and Kombrink, H. Geological Society London Special Publications, 494 . Geological Society, London, Chapter 26.

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Publication Date: 2020-12-10

Description: Hydrocarbon exploration in the North Sea Basin has revealed a multitude of focused fluid conduits, which manifest in seismic data as pipe or chimney structures that in some instances are connected to underlying hydrocarbon reservoirs. 3D seismic data from the eastern margin of the East Shetland Platform (ESP) reveal the presence of more than 450 focused fluid conduits. Most of these initiate at the Base Tertiary Unconformity (BTU) and crosscut the overlying sediments. The focused fluid conduits correlate with intra-platform basin structures beneath the BTU and with permeable sediments lobes, channels and deltaic units in the overlying Paleocene to Eocene successions, which include known hydrocarbon reservoirs (e.g. Bressay, Bentley, Skipper or Piper). Clusters of pipes associated with other channels and deltaic units may indicate the presence of additional prospects at the eastern margin of the ESP. Our study highlights the potential of using seismically imaged focused fluid system analyses in hydrocarbon exploration in platform areas on both sides of the Viking Graben and other frontier areas as they reveal the presence of working hydrocarbon charge pathways.

Type: Book chapter , NonPeerReviewed

Format: text

DOI: 10.1144/SP494-2019-26

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7

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Submarine spreading in the Storegga Slide, Norwegian Sea (2016)

Micallef, Aaron ; Masson, D. G. ; Berndt, Christian ; [et al.]

GSL (Geological Society London)

In: In: Atlas of submarine glacial landforms: modern, Quaternary and ancient. , ed. by Dowdeswell, J. A., Canals, M., Jakobsson, M., Todd, B. J., Dowdeswell, E. K. and Hogan, K. A. Memoirs of the Geological Society of London, 46 . GSL (Geological Society London), London, pp. 411-412. ISBN 978-1-78620-268-0

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Publication Date: 2021-05-10

Description: Spreading is a type of mass movement where a sediment unit is extended and broken up into coherent blocks that are displaced and tilted along a planar slip. High-resolution seafloor data demonstrate that spreading is a common style of submarine mass movement. Submarine spreading is clearly exemplified in the Storegga Slide, Norwegian margin (Fig. 1a, b). The slide occurred 8100 + 250 cal a BP as a retrogressive slope failure (Haflidason et al. 2005). It is one of the largest known submarine slides and the site of repeated sliding activity. Failures on the Norwegian margin are linked strongly to the growth and retreat of the Fennoscandian ice sheets, in particular to the alternating deposition of glacigenic debrites and basal and deformation tills during glacial maxima (e.g. O1–O2 30–15 ka and O4–O7 200–130 ka sub-units of the Naust Formation), and of fine-grained glacimarine, hemipelagic and contouritic sediments during interglacials (e.g. O3 130–30 ka sub-unit of the Naust Formation). The Naust sub-units are described in full in Berg et al. (2005). Differences in the geotechnical properties of these sediments, coupled with seismicity, rapid sediment deposition, associated high pore pressures and the regional topography and structural setting, are responsible for .20 slope failures across the region during the Quaternary (Solheim et al. 2005).

Type: Book chapter , NonPeerReviewed

Format: text

DOI: 10.1144/M46.88

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8

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Volcanic-Island Lateral Collapses and Their Submarine Deposits (2021)

Watt, Sebastian F. L. ; Karstens, Jens ; Berndt, Christian

Springer

In: In: Volcanic Debris Avalanches. , ed. by Roverato, M., Dufresne, A. and Procter, J. Springer, Cham, pp. 255-279, 25 pp. ISBN 978-3-030-57411-6

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Publication Date: 2021-01-19

Description: Landslide deposits offshore many volcanic islands provide evidence of catastrophic lateral collapses. These deposits span a larger volume range than their continental equivalents, and can generate devastating tsunamis. All historical volcanic-island lateral collapses have occurred in arc settings, and have been characterised by rapid failure and efficient tsunami generation. The varied morphology of their deposits is influenced both by lithological properties and the nature of the substrate. Many deposits show evidence of extensive seafloor erosion and transformation into debris flows, and the propagation of frontally-confined sediment deformation beyond and beneath the primary deposit. Mobilised volumes can far exceed that of the initial failure, and accurate deposit interpretation requires internal geophysical imaging and sampling. Around intraplate ocean-island volcanoes, multi-unit turbidites suggest that lateral collapses may occur in discrete stages; although this would reduce their overall tsunamigenic potential, the volumes of individual stages of collapse remain very large. Numerical models of both landslide and tsunami processes in ocean-island settings are difficult to test, and the smaller collapses that typify island arcs are an important focus of research due to their higher global frequency, availability of direct failure and tsunami observations, and a need to better understand the signals of incipient collapse to develop approaches for tsunami hazard mitigation.

Type: Book chapter , NonPeerReviewed

Format: text

DOI: 10.1007/978-3-030-57411-6_10

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9

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Geomechanical behaviour of gassy soils and implications for submarine slope stability - a literature analysis (2020)

Kaminski, P. ; Urlaub, Morelia ; Grabe, J. ; [et al.]

Geological Society of London

In: In: Subaqueous Mass Movements and their Consequences: Advances in Process Understanding, Monitoring and Hazard. , ed. by Georgiopoulou, A. Special Publications Geological Society London, 500 . Geological Society of London, London, pp. 277-288.

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Publication Date: 2020-07-21

Description: Submarine slope failures pose a direct threat to seafloor installations and coastal communities. Here, we evaluate the influence of free gas on the soil’s shear strength and submarine slope failures in areas with gassy soils based on an extensive literature review. We identify two potential destabilization mechanisms: gas bubbles in the pore space lead to a reduced shear strength of the soil and/or gas induces excess pore pressures that consequently reduce the effective stress in the soil. Our evaluation of the reported mechanical and hydraulic behaviour of gassy sediments indicates that the unfavourable impact of entrapped gas on a soil’s shearing resistance is not sufficient to trigger large scale slope failures. Liquefaction failure due to high gas pressures is, however, a viable scenario in coarse-grained soils. Transferring the gas influence on the soil mechanical behaviour to constitutive models is identified as the most important prerequisite for a successful future analysis of slope stability.

Type: Book chapter , NonPeerReviewed

Format: text

DOI: 10.1144/SP500-2019-149

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