The physics of gas chimney and pockmark formation, with implications for assessment of seafloor hazards and gas sequestration

Cathles, L. M.; Zheng, Shuai; Chen, Duofu

doi:10.1016/j.marpetgeo.2009.09.010

Cited by 215 publications

(196 citation statements)

References 34 publications

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“…5). Other indications of gas in sediments, such as acoustically disrupted columns, or "chimneys" (sensu Cathles et al, 2010), were not observed in any of the estuaries.…”

Section: Natural Gas (Ng)mentioning

confidence: 84%

Shallow stratigraphic control on pockmark distribution in north temperate estuaries

et al. 2012

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Pockmark fields occur throughout northern North American temperate estuaries despite the absence of extensive thermogenic hydrocarbon deposits typically associated with pockmarks. In such settings, the origins of the gas and triggering mechanism(s) responsible for pockmark formation are not obvious. Nor is it known why pockmarks proliferate in this region but do not occur south of the glacial terminus in eastern North America. This paper tests two hypotheses addressing these knowledge gaps: 1) the region's unique sea-level history provided a terrestrial deposit that sourced the gas responsible for pockmark formation; and 2) the region's physiography controls pockmarks distribution. This study integrates over 2500 km of high-resolution swath bathymetry, Chirp seismic reflection profiles and vibracore data acquired in three estuarine pockmark fields in the Gulf of Maine and Bay of Fundy. Vibracores sampled a hydric paleosol lacking the organic-rich upper horizons, indicating that an organic-rich terrestrial deposit was eroded prior to pockmark formation. This observation suggests that the gas, which is presumably responsible for the formation of the pockmarks, originated in Holocene estuarine sediments (loss on ignition 3.5-10%), not terrestrial deposits that were subsequently drowned and buried by mud. The 7470 pockmarks identified in this study are non-randomly clustered. Pockmark size and distribution relate to Holocene sediment thickness (r 2 =0.60), basin morphology and glacial deposits. The irregular underlying topography that dictates Holocene sediment thickness may ultimately play a more important role in temperate estuarine pockmark distribution than drowned terrestrial deposits. These results give insight into the conditions necessary for pockmark formation in nearshore coastal environments.Published by Elsevier B.V.

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“…5). Other indications of gas in sediments, such as acoustically disrupted columns, or "chimneys" (sensu Cathles et al, 2010), were not observed in any of the estuaries.…”

Section: Natural Gas (Ng)mentioning

confidence: 84%

Shallow stratigraphic control on pockmark distribution in north temperate estuaries

et al. 2012

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“…The failure of the capillary pressure was suggested as the main cause for the formation of the pockmarks. Seal fails when buoyancy pressure exceeds the capillary pressure during hydrate crystallization and gas accumulations, which leads to the formation of large escape of gases to the seafloor initiating dissolution of the surrounding sediment by ocean water and forms pockmarks (Cathles et al, 2010). The linear arrangement of pockmarks indicates their association with fault zones (Haskell et al, 1999).…”

Section: Pockmarksmentioning

confidence: 99%

Deep-seated faults and hydrocarbon leakage in the Snøhvit Gas Field, Hammerfest Basin, Southwestern Barents Sea

Mohammedyasin

Lippard

Omosanya

et al. 2016

Marine and Petroleum Geology

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High-quality 3D seismic data are used to analyze the history of fault growth and hydrocarbon leakage in the Snøhvit Field, southwestern Barents Sea. The aim of this work is to evaluate the role of tectonic fracturing as a mechanism driving fluid-flow in the study area. To achieve this aim, an integrated approach including seismic interpretation, multiple seismic attribute analysis, fault modeling and displacement analysis was used.The six major faults in the study area are dip-slip normal faults which are characterized by complex lateral and vertical segmentation. The three main episodes of fault reactivation interpreted were in late Jurassic (Kimmeridgian), early Cretaceous and Paleocene times. Fault reactivation in the study area is mainly through dip-linkage. Throw-distance plots of the representative faults also revealed along-strike linkage and multi-skewed C-type profiles. The throw profiles show that faults in the study area evolved through polycyclic activity involving both blind propagation, syn-sedimentary activity and that they have their maximum displacement at the reservoir zone. The expansion and growth indices provide evidence for coeval fault activity with sedimentation and interaction of the faults with a free surface during their evolution.

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“…A model by Woolsey et al (1975) simulating "diatreme emplacements by 57 fluidization" supports this theory. Recently, Cathles et al (2010) came up with a 58 conceptual model of pockmark and gas chimney formation. They assume that there 59 is a capillary seal which traps the gas in the deeper sediment.…”

Section: But Many Published Examples Indicate Formation 38mentioning

confidence: 99%

Characterization of microbial activity in pockmark fields of the SW-Barents Sea

et al. 2012

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15 16Multibeam bathymetry revealed the occurrence of numerous craterlike depressions, 17 so-called pockmarks, on the sea floor of the Hammerfest Basin and the Loppa High, 18 south-western Barents Sea. To investigate whether these pockmarks are related to 19 ongoing gas seepage, microbial processes associated with methane metabolism 20 were analyzed using geochemical, biogeochemical and microbiological techniques. 21Gravity cores were collected along transects crossing individual pockmarks, allowing 22 a direct comparison between different locations inside (assumed activity center), on 23 the rim, and outside of a pockmark (reference sites). Concentrations of hydrocarbons 24 in the sediment, particularly methane, were measured as headspace (free) gas, and 25 in the occluded and adsorbed gas fraction. Down to a depth of 2.6 m below sea floor 26 2 (mbsf) sulfate reduction rates were quantified by radiotracer incubations. 27Concentrations of dissolved sulfate in the porewater were determined as well. Neither 28 the sulfate profiles nor the gas measurements show any evidence of microbial activity 29 or active fluid venting. Methane concentrations and sulfate reduction rates were 30 extremely low or even below the detection limit. The results show that the observed 31 sediment structures are most likely paleo-pockmarks, their formation probably 32 occurred during the last deglaciation. 33 34 Introduction 35Pockmarks are craterlike depressions in the seabed that form due to expulsion of 36

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The physics of gas chimney and pockmark formation, with implications for assessment of seafloor hazards and gas sequestration

Cited by 215 publications

References 34 publications

Shallow stratigraphic control on pockmark distribution in north temperate estuaries

Shallow stratigraphic control on pockmark distribution in north temperate estuaries

Deep-seated faults and hydrocarbon leakage in the Snøhvit Gas Field, Hammerfest Basin, Southwestern Barents Sea

Characterization of microbial activity in pockmark fields of the SW-Barents Sea

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