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Thermal Characterization of Pockmarks Across Vestnesa and Svyatogor Ridges, Offshore Svalbard (2021)

Riedel, M. ; Villinger, H. ; Freudenthal, T. ; [et al.]

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Publication Date: 2021-07-01

Description: The Svalbard margin represents one of the northernmost gas hydrate provinces worldwide. Vestnesa Ridge (VR) and Svyatogor Ridge (SR) west of Svalbard are two prominent sediment drifts showing abundant pockmarks and sites of seismic chimney structures. Some of these sites at VR are associated with active gas venting and were the focus of drilling and coring with the seafloor‐deployed MARUM‐MeBo70 rig. Understanding the nature of fluid migration and gas hydrate distribution requires (among other parameters) knowledge of the thermal regime and in situ gas and pore fluid composition. In situ temperature data were obtained downhole at a reference site at VR defining a geothermal gradient of ~78 mK m−1 (heat flow ~95 mW m−2). Additional heat probe data were obtained to describe the thermal regime of the pockmarks. The highest heat flow values were systematically seen within pockmark depressions and were uncorrelated to gas venting occurrences. Heat flow within pockmarks is typically ~20 mW m−2 higher than outside pockmarks. Using the downhole temperature data and gas compositions from drilling we model the regional base of the gas hydrate stability zone (BGHSZ). Thermal modeling including topographic effects suggest a BGHSZ up to 40 m deeper than estimated from seismic data. Uncertainties in sediment properties (velocity and thermal conductivity) are only partially explaining the mismatch. Capillary effects due to small sediment grain sizes may shift the free gas occurrence above the equilibrium BGHSZ. Changes in gas composition or pore fluid salinity at greater depth may also explain the discrepancy in observed and modeled BGHSZ.

Description: Key Points: Heat flow variations across the Vestnesa and Svyatogor Ridges off Svalbard are correlated with seismic data showing gas hydrate BSRs. In situ temperatures were measured with the MARUM MeBo70 rig up to ~60 mbsf indicating a background thermal gradient of ~78°C/km. Heat flow is significantly higher within the pockmarks but is not correlated to the occurrence of gas venting.

Description: Statoil http://dx.doi.org/10.13039/501100004342

Description: CAGE

Description: German Research Foundation (DFG)

Keywords: 622.15 ; Svalbard margin ; heat flow ; gas hydrate ; pockmark ; MeBo drilling

Type: article

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Local Seismicity and Sediment Deformation in the West Svalbard Margin: Implications of Neotectonics for Seafloor Seepage (2023)

Domel, P ; Plaza‐Faverola, A ; Schlindwein, V ; [et al.]

American Geophysical Union (AGU)

In: EPIC3Geochemistry Geophysics Geosystems, American Geophysical Union (AGU), 24(12), ISSN: 1525-2027

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Publication Date: 2024-01-22

Description: In the Fram Strait, mid-ocean ridge spreading is represented by the ultra-slow system of the Molloy Ridge, the Molloy Transform Fault and the Knipovich Ridge. Sediments on oceanic and continental crust are gas charged and there are several locations with documented seafloor seepage. Sedimentary faulting shows recent stress release in the sub-surface, but the drivers of stress change and its influence on fluid flow are not entirely understood. We present here the results of an 11-month-long ocean bottom seismometer survey conducted over the highly faulted sediment drift northwards from the Knipovich Ridge to monitor seismicity and infer the regional state of stress. We obtain a detailed earthquake catalog that improves the spatial resolution of mid-ocean ridge seismicity compared with published data. Seismicity at the Molloy Transform Fault is occurring southwards from the bathymetric imprint of the fault, as supported by a seismic profile. Earthquakes in the northern termination of the Knipovich Ridge extend eastwards from the ridge valley, which together with syn-rift faulting identified in seismic reflection data, suggests that a portion of the currently active spreading center is buried under sediments away from the bathymetric expression of the rift valley. This hints at the direct link between crustal rifting processes and faulting in shallow sediments. Two earthquakes occur close to the seepage system of the Vestnesa Ridge further north from the network. We suggest that deeper rift structures, reactivated by gravity and/or post-glacial subsidence, may lead to accommodation of stress through shallow extensional faults, therefore impacting seepage dynamics.

Repository Name: EPIC Alfred Wegener Institut

Type: Article , isiRev

Format: application/pdf

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High-Resolution Core-Log-Seismic Integration and Igneous Seismic Geomorphology of IODP Expedition 396 Sites on the Mid-Norwegian Margin (2023)

Planke, S. ; Lebedeva-Ivanova, N. ; Bünz, S. ; [et al.]

European Association of Geoscientists & Engineers

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Publication Date: 2023-08-11

Description: The breakup of the Norwegian-Greenland Sea 56 million years ago was associated with massive basaltic magmatism and a short-lived global warming episode, the Paleocene-Eocene Thermal Maximum (PETM). Scientific drilling in 2021 targeted sediments and volcanic rocks on the mid-Norwegian margin to test hypotheses related to the formation of large igneous provinces as well as global warming associated potentially with the igneous activity. High-resolution 3D site survey data facilitated optimal borehole locations during the drilling; key reflections were targeted using the high-resolution 3D data, and PETM stratigraphic intervals were recognized during shipboard core descriptions. Igneous seismic geomorphological interpretation, furthermore, reveals distinct volcanic morphologies on the marginal high, related to different volcanic emplacement environments.

Type: Conference or Workshop Item , NonPeerReviewed

Format: text

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Bottom-simulating reflector dynamics at Arctic thermogenic gas provinces: An example from Vestnesa Ridge, offshore west Svalbard (2017)

Plaza-Faverola, A. ; Vadakkepuliyambatta, S. ; Hong, W.-L. ; [et al.]

AGU (American Geophysical Union) | Wiley

In: Journal of Geophysical Research: Solid Earth, 122 (6). pp. 4089-4105.

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Publication Date: 2020-02-06

Description: The Vestnesa Ridge comprises a 〉100 km long sediment drift located between the western continental slope of Svalbard and the Arctic mid-ocean ridges. It hosts a deep water (〉1000 m) gas hydrate and associated seafloor seepage system. Near-seafloor headspace gas compositions and its methane carbon isotopic signature along the ridge indicate a predominance of thermogenic gas sources feeding the system. Prediction of the base of the gas hydrate stability zone for theoretical pressure and temperature conditions and measured gas compositions results in an unusual underestimation of the observed bottom-simulating reflector (BSR) depth. The BSR is up to 60 m deeper than predicted for pure methane and measured gas compositions with 〉99% methane. Models for measured gas compositions with 〉4% higher-order hydrocarbons result in a better BSR approximation. However, the BSR remains 〉20 m deeper than predicted in a region without active seepage. A BSR deeper than predicted is primarily explained by unaccounted spatial variations in the geothermal gradient and by larger amounts of thermogenic gas at the base of the gas hydrate stability zone. Hydrates containing higher-order hydrocarbons form at greater depths and higher temperatures and contribute with larger amounts of carbons than pure methane hydrates. In thermogenic provinces, this may imply a significant upward revision (up to 50% in the case of Vestnesa Ridge) of the amount of carbon in gas hydrates.

Type: Article , PeerReviewed

Format: text

DOI: 10.1002/2016JB013761

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Ocean bottom seismometer investigations in the Ormen Lange area offshore mid-Norway provide evidence for shallow gas layers in subsurface sediments (2005)

Mienert, J. ; Bünz, S. ; Guidard, S. ; [et al.]

Elsevier

In: Marine and Petroleum Geology, 22 (1-2). pp. 287-297.

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Publication Date: 2017-07-21

Description: A multi-component Ocean Bottom Seismometer (OBS) survey in the Ormen Lange area of the Storegga Slide constrained the existence of free gas and possibly gas hydrates in the shallow subsurface. The three investigated areas (A, B, C) lie in close vicinity to the slide scar above one of the largest deep-water gas reservoirs on the mid-Norwegian margin. Generally, P-wave and S-wave velocities are high compared to average velocities at a given burial depth due to an exposure of deeper sediments as a consequence of sediment mass movement by the Storegga slide. Indications for the presence of gas within the sediments exist for two of the three investigated areas. The gas accumulates beneath less permeable layers of glacigenic debris flow deposits. Average gas concentration of pore space in both areas is 0.9% (area A) and 0.15% (area B). The geophysical data do not allow a conclusive answer about the occurrence of gas hydrates. Their presence might be masked by high-velocity debris flow deposits, which occur in the subsurface. Nevertheless, gas hydrate concentrations of pore space have been estimated to about 9% in area A and 7% in area B.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/j.marpetgeo.2004.10.020

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Natural Hydrofractures, Gas Seeps, and Hydrates Offshore Hawke’s Bay: A High-Resolution 3D Seismic Investigation (2013)

Plaza-Faverola, A. ; Pecher, I. ; Crutchley, Gareth ; [et al.]

In: [Poster] In: New Zealand Petroleum Conference, 29.04.-01.05.2013, Auckland, New Zealand .

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Publication Date: 2013-08-12

Type: Conference or Workshop Item , NonPeerReviewed

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Evaluating propensity of leakage with Bayesian Belief Nets (BN) (2014)

Flach, T. ; Solomon, S. ; Cavanagh, A. ; [et al.]

In: [Poster] In: (GHGT-12) International Conference on Greenhouse Gas Technology , 05.-09.10.2014, Austin, Texas, USA .

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Publication Date: 2014-12-04

Type: Conference or Workshop Item , NonPeerReviewed

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Geological controls on the Storegga gas-hydrate system of the mid-Norwegian continental margin (2003)

Bünz, S. ; Mienert, J. ; Berndt, Christian

Elsevier

In: Earth and Planetary Science Letters, 209 (3-4). pp. 291-307.

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Publication Date: 2016-11-15

Description: The geologic setting of the formerly glaciated mid-Norwegian continental margin exerts specific controls on the formation of a bottom-simulating reflector (BSR) and the inferred distribution of gas hydrates. On the continental slope the lithology of glacigenic debris flow deposits and pre-glacial basin deposits of the Kai Formation prevent gas-hydrate formation, because of reduced pore size, reduced water content and fine-grained sediment composition. Towards the continental shelf, the shoaling and pinch-out of the gas-hydrate stability zone terminates the area of gas-hydrate growth. These geological controls confine the occurrence of gas hydrates and ensuing formation of a BSR to a small zone along the northern flank of the Storegga submarine slide and the slide area itself. A BSR inside the slide area indicates a dynamically adjusting gas-hydrate system to post-slide pressure–temperature equilibrium conditions. These observations, together with widespread evidence for fluid flow and deep-seated hydrocarbon reservoirs, suggest that the formation of BSR and gas hydrates on the mid-Norwegian continental margin is dominated by an advection of gas from the strata distinctly beneath the gas-hydrate stability zone. Fluids migrate upward within the Naust Formation and are deflected laterally by hydrated sediments and less permeable layers. Gases continually accumulate at the top of the slope, where overpressure eventually results in the formation of blow-out pipes and consequent pockmark development on the seabed.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/S0012-821X(03)00097-9

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Seismic character of bottom simulating reflectors: Examples from the mid-Norwegian margin (2004)

Berndt, Christian ; Bünz, S. ; Clayton, T. ; [et al.]

Elsevier

In: Marine and Petroleum Geology, 21 (6). pp. 723-733.

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Publication Date: 2017-07-21

Description: Three classes of bottom simulating reflectors (BSR) cross-cut the post-breakup sediments of the mid-Norwegian margin. The first class is caused by free gas at the base of the pressure- and temperature-dependent gas hydrate stability zone. The second class of BSR is caused by the diagenetic transition from opal A to opal CT. The third class of BSR is always observed underneath the opal A/opal CT transition, but heat flow data and the amplitude characteristics of this arrival exclude one of the known silicate diagenetic transitions or gas hydrates as the explanation for this reflector. ODP Site 643 drilling results from the Vøring Plateau suggest two possible processes as the reason for this third BSR: (a) smectite illite conversion or (b) a sudden increase in the abundance of authigenic carbonates. The genesis of both is pressure- and temperature-dependent and could potentially result in a cross-cutting seismic reflector. The data are not conclusive as to which process is causing the third class of observed BSR.

Type: Article , PeerReviewed

Format: text

DOI: 10.1016/j.marpetgeo.2004.02.003

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