Methane Hydrate Accumulation along the Western Nankai Trough

Aoki, Yasuhiro; Shimizu, Shoshiro; Yamane, Terumasa; Tanaka, Tomoyuki; Nakayama, Keisuke; Hayashi, T.; Okuda, Y.

doi:10.1111/j.1749-6632.2000.tb06767.x

Cited by 9 publications

(7 citation statements)

References 7 publications

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“…Pore water flow can be focused by layers of high permeability in sediments (Hovland et al, 1997;Aoki et al, 2000;Flemings et al, 2002). Lateral flow steered by sediment permeability predicts expulsion of fluid near the base of the continental slope off New Jersey, consistent with the observed patterns of porewater seeps, and leading to nucleation of landslides from the base of the slope, consistent with the observation of submarine canyons on continental margins (Dugan and Flemings, 2000).…”

Section: Aqueous Flowsupporting

confidence: 58%

“…Seismic studies at Blake Ridge have observed the presence of bubbles along faults in the sediment matrix (Taylor et al, 2000). Faults have been correlated with sites of methane gas emission from the sea floor (Aoki et al, 2000;Zuhlsdorff et al, 2000;Zuhlsdorff and Spiess, 2004). Seismic studies often show "wipeout zones" where the bubble zone beneath the hydrate stability zone is missing, and all of the layered structure of the sediment column within the stability zone is smoothed out.…”

Section: Gas Migrationmentioning

confidence: 99%

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Methane hydrate stability and anthropogenic climate change

2007

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Abstract. Methane frozen into hydrate makes up a large reservoir of potentially volatile carbon below the sea floor and associated with permafrost soils. This reservoir intuitively seems precarious, because hydrate ice floats in water, and melts at Earth surface conditions. The hydrate reservoir is so large that if 10% of the methane were released to the atmosphere within a few years, it would have an impact on the Earth's radiation budget equivalent to a factor of 10 increase in atmospheric CO 2 .Hydrates are releasing methane to the atmosphere today in response to anthropogenic warming, for example along the Arctic coastline of Siberia. However most of the hydrates are located at depths in soils and ocean sediments where anthropogenic warming and any possible methane release will take place over time scales of millennia. Individual catastrophic releases like landslides and pockmark explosions are too small to reach a sizable fraction of the hydrates. The carbon isotopic excursion at the end of the Paleocene has been interpreted as the release of thousands of Gton C, possibly from hydrates, but the time scale of the release appears to have been thousands of years, chronic rather than catastrophic.The potential climate impact in the coming century from hydrate methane release is speculative but could be comparable to climate feedbacks from the terrestrial biosphere and from peat, significant but not catastrophic. On geologic timescales, it is conceivable that hydrates could release as much carbon to the atmosphere/ocean system as we do by fossil fuel combustion.

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Section: Aqueous Flowsupporting

confidence: 58%

Section: Gas Migrationmentioning

confidence: 99%

Methane hydrate stability and anthropogenic climate change

2007

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“…The host sediment is assumed to be weak and unconsolidated sediment, with S H = 0.1. Such HBS are typical of a widely occurring type of hydrate deposits (Moridis and Kowalsky 2006;Aoki at al. 2000), both in terms of texture (soft and structurally weak muds and clays are common at the ocean floor, with the cementing hydrates providing the only structural strength of the HBS) and hydrate saturation (Klauda and Sandler 2005).…”

Section: The Numerical Simulatormentioning

confidence: 97%

Numerical Studies on the Geomechanical Stability of Hydrate-Bearing Sediments

2009

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The thermal and mechanical loading of oceanic hydrate-bearing sediments (HBS) can result in hydrate dissociation and a significant pressure increase with potentially adverse consequences on the integrity and stability of the wellbore assembly, the HBS, and the bounding formations. The perception of HBS instability, coupled with insufficient knowledge of their geomechanical behavior and the absence of predictive capabilities, has resulted in a strategy of avoidance of HBS when locating offshore production platforms and can impede the development of hydrate deposits as gas resources.In this study, we investigate coupled (interacting) hydraulic, thermodynamic, and geomechanical behavior of oceanic HBS in three cases. The first involves hydrate heating as warm fluids from deeper conventional reservoirs ascend to the ocean floor through uninsulated pipes intersecting the HBS. The second case describes system response during gas production from a hydrate deposit, and the third involves mechanical loading caused by the weight of structures placed on the ocean floor overlying the HBS.For the analysis of the geomechanical stability of HBS, we developed and used a numerical simulator that integrates a commercial geomechanical simulator and a simulator describing the coupled processes of fluid flow, heat transport, and thermodynamic behavior in the HBS. Our simulation results indicate that the stability of HBS in the vicinity of warm pipes may be affected significantly. Gas production from oceanic deposits may also affect the geomechanical stability of HBS under the conditions that are deemed desirable for production. Conversely, the increased pressure caused by the weight of structures on the ocean floor increases the stability of underlying hydrates.Geomechanical Properties of the HBS To simulate the mechanical behavior of the HBS, we apply an elastoplastic mechanical constitutive law with a modified Mohr-Coulomb failure criterion. The elastoplastic properties of the HBS

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“…Such a HBS is typical of a widely-occurring type of hydrate deposits 14,24 both in terms of texture (soft and structurally weak muds and clays are common at the ocean floor, with the cementing hydrates providing the only structural strength of the HBS) and hydrate saturation 25 . In this case we investigate the geomechanical behavior of oceanic HBS at or near the ocean floor, in which anchors or foundation of structures (such as offshore platforms) are installed.…”

Section: Problem 3: Loading Caused By the Weight Of Structures Placedmentioning

confidence: 99%

Numerical Studies on the Geomechanical Stability of Hydrate-Bearing Sediments

Rutqvist

Moridis

2007

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TX 75083-3836, U.S.A., fax 01-972-952-9435. AbstractThe thermal and mechanical loading of oceanic Hydrate-Bearing Sediments (HBS) can result in hydrate dissociation and a significant pressure increase, with potentially adverse consequences on the integrity and stability of the wellbore assembly, the HBS, and the bounding formations. The perception of HBS instability, coupled with insufficient knowledge of their geomechanical behavior and the absence of predictive capabilities, have resulted in a strategy of avoidance of HBS when locating offshore production platforms, and can impede the development of hydrate deposits as gas resources.In this study we investigate in three cases of coupled hydraulic, thermodynamic and geomechanical behavior of oceanic hydrate-bearing sediments. The first involves hydrate heating as warm fluids from deeper conventional reservoirs ascend to the ocean floor through uninsulated pipes intersecting the HBS. The second case describes system response during gas production from a hydrate deposit, and the third involves mechanical loading caused by the weight of structures placed on the ocean floor overlying hydrate-bearing sediments.For the analysis of the geomechanical stability of HBS, we developed and used a numerical model that integrates a commercial geomechanical code and a simulator describing the coupled processes of fluid flow, heat transport and thermodynamic behavior in the HBS. Our simulation results indicate that the stability of HBS in the vicinity of warm pipes may be significantly affected, especially if the sediments are unconsolidated and more compressible. Gas production from oceanic deposits may also affect the geomechanical stability of HBS under the conditions that are deemed desirable for production. Conversely, the increased pressure caused by the weight of structures on the ocean floor increases the stability of underlying hydrates.

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Methane Hydrate Accumulation along the Western Nankai Trough

Cited by 9 publications

References 7 publications

Methane hydrate stability and anthropogenic climate change

Methane hydrate stability and anthropogenic climate change

Numerical Studies on the Geomechanical Stability of Hydrate-Bearing Sediments

Numerical Studies on the Geomechanical Stability of Hydrate-Bearing Sediments

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