Geological settings and controls of fluid migration and associated seafloor seepage features in the north Irish Sea

Coughlan, Mark; Roy, Srikumar; O’Sullivan, Catherine; Clements, Annika; O’Toole, Ronan; Plets, Ruth

doi:10.1016/j.marpetgeo.2020.104762

Cited by 17 publications

(9 citation statements)

References 55 publications

(13 reference statements)

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“…The continuous passage of gas through the same area may cause the development of open channels (or chimneys) in the sediment which direct the flow of gas to a single localised point on the seabed, forming a seep [29][30][31] .…”

Section: Gas Seep Acousticsmentioning

confidence: 99%

“…A subsea gas seep is broadly defined by the continuous release of gas from the seabed into the water column. There is no set magnitude for the flux of gas from a seep [29][30][31] , meaning the term encompasses seeps that release tens to millions of bubbles per minute. Similarly, there is no strictly defined time scales for being continuous, some seeps are born and die within a few hours, some are only active for certain times of the day or year while others have been active for centuries 30,32,33 .…”

Section: Gas Seep Acousticsmentioning

confidence: 99%

“…There is no set magnitude for the flux of gas from a seep [29][30][31] , meaning the term encompasses seeps that release tens to millions of bubbles per minute. Similarly, there is no strictly defined time scales for being continuous, some seeps are born and die within a few hours, some are only active for certain times of the day or year while others have been active for centuries 30,32,33 . It is also worth noting a seep does not have to be in sediment, it may also come from exposed bedrock or even manmade features such as leaking pipes.…”

Section: Gas Seep Acousticsmentioning

confidence: 99%

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Chapter 5: Ambient Bubble Acoustics -Seep, Rain and Wave Noise

Roche

Leighton

White

et al. 2022

Preprint

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Section: Gas Seep Acousticsmentioning

confidence: 99%

Section: Gas Seep Acousticsmentioning

confidence: 99%

Section: Gas Seep Acousticsmentioning

confidence: 99%

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Chapter 5: Ambient Bubble Acoustics -Seep, Rain and Wave Noise

Roche

Leighton

White

et al. 2022

Preprint

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“…The WISMB covers an extensive area with water depths up to 100 m that is filled with substantial thicknesses (up to 40 m) of marine, Holocene sediments 22 . Previous investigations 23 – 25 in the area have identified four stratigraphic units in the WISMB consisting of a basal subglacial (lodgement) till (Unit 4) emplaced by the Irish Sea Ice Stream (ISIS) as it advanced across the area. Unit 4 overlies irregular bedrock.…”

Section: Introductionmentioning

confidence: 99%

Distributed acoustic sensing for active offshore shear wave profiling

Trafford

Ellwood²,

Wacquier

et al. 2022

Sci Rep

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The long-term sustainability of the offshore wind industry requires the development of appropriate investigative methods to enable less conservative and more cost-effective geotechnical engineering design. Here we describe the novel use of distributed acoustic sensing (DAS) as part of an integrated approach for the geophysical and geotechnical assessment of the shallow subsurface for offshore construction. DAS was used to acquire active Scholte-wave seismic data at several locations in the vicinity of a planned windfarm development near Dundalk Bay, Irish Sea. Complimentary additional datasets include high-resolution sparker seismic reflection, cone penetration test (CPT) data and gravity coring. In terms of fibre optic cable selection, a CST armoured cable provided a reasonable compromise between performance and reliability in the offshore environment. Also, when used as a seismic source, a gravity corer enabled the fundamental mode Scholte-wave to be better resolved than an airgun, and may be more suitable in environmentally sensitive areas. Overall, the DAS approach was found to be effective at rapidly determining shear wave velocity profiles in areas of differing geological context, with metre scale spatial sampling, over multi-kilometre scale distances. The application of this approach has the potential to considerably reduce design uncertainty and ultimately reduce levelised costs of offshore wind power generation.

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“…Seismic and acoustic explorations have been widely used for investigating gas-related anomalous reflections and mapping gas distribution in sub-bottom sediments (Ye et al, 2003;Hu et al, 2012;Cukur et al, 2013;Schneider von Deimling et al, 2013: Hu et al, 2016Yang et al, 2019). Because gas-charged sediments can effectively absorb and scatter the energy of sound waves, which rapidly attenuate inner gas-charged sediments along the vertical direction (Hovland and Judd, 1988;Ye et al, 2003;Coughlan et al, 2021;Toker and Tur, 2021;Yang et al, 2022b), stratal structures usually display acoustic anomalous reflections including acoustic turbidity, acoustic blanking, enhanced reflection, bright spot, gas chimney, and pockmark (Ye et al, 2003;Visnovitz et al, 2015;Coughlan et al, 2021;Toker and Tur, 2021). Shallow gas has been surveyed to be widely distributed in coastal zones, such as the Gulf of Mexico, the Baltic Sea, and the East China Sea (Hovland and Judd, 1988;Zhang et al, 2004;Zhang et al, 2008;Lin et al, 2015;Liu et al, 2019;Chen et al, 2020).…”

mentioning

confidence: 99%

Controls on shallow gas distribution, migration, and associated geohazards in the Yangtze subaqueous delta and the Hangzhou Bay

Song

Fan²,

Su³

et al. 2023

Front. Mar. Sci.

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Shallow gas is generally extensively distributed in the Holocene muddy sediments and gas seepage has been increasingly reported to induce geohazards in coastal seas, but controls on gas distribution and migration remain elusive. This study explores gas distribution and migration in the Yangtze subaqueous delta and the Hangzhou Bay using high-resolution acoustic profiles and core data. Shallow gas is widely detected by the common presence of acoustic anomalous reflections including enhanced reflection, gas chimney, bright spot, acoustic blanking, and acoustic turbidity. The gas front depth is generally less than 17.5 m, and is meanly shallower in the Hangzhou Bay than in the Yangtze subaqueous delta because of relatively shallower water depth and coarser Holocene sediments in the Hangzhou Bay. Shallow gas is inferred to be a biogenic product, and its distribution is highly contingent on the Holocene stratal thickness and water depth. Active gas migration and seepages are evident, and recently increasing occurrences of gas seepage can be ascribed to global warming and seabed erosion due to sediment deficit. The findings warn us to pay more attention to the positive feedback loops of gas seepages with global warming and seabed erosion for the associated geohazard prediction and reduction, typically in the highly developed coastal regions.

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Geological settings and controls of fluid migration and associated seafloor seepage features in the north Irish Sea

Cited by 17 publications

References 55 publications

Chapter 5: Ambient Bubble Acoustics -Seep, Rain and Wave Noise

Chapter 5: Ambient Bubble Acoustics -Seep, Rain and Wave Noise

Distributed acoustic sensing for active offshore shear wave profiling

Controls on shallow gas distribution, migration, and associated geohazards in the Yangtze subaqueous delta and the Hangzhou Bay

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