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Dynamics of fault-fluid-hydrate system around a shale-cored anticline in deepwater Nigeria

Gas hydrates were recovered by coring at the eastern border of a shale‐cored anticline in the eastern Niger Delta. To characterize the link between faults and fluid release and to identify the role of fluid flow in the gas hydrate dynamics, three piezometers were deployed for periods ranging from 38...

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Bibliographic Details
Published in:Journal of Geophysical Research 2011-12, Vol.116 (B12), p.n/a, Article B12110
Main Authors: Sultan, N., Riboulot, V., Ker, S., Marsset, B., Géli, L., Tary, J. B., Klingelhoefer, F., Voisset, M., Lanfumey, V., Colliat, J. L., Adamy, J., Grimaud, S.
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Language:English
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Summary:Gas hydrates were recovered by coring at the eastern border of a shale‐cored anticline in the eastern Niger Delta. To characterize the link between faults and fluid release and to identify the role of fluid flow in the gas hydrate dynamics, three piezometers were deployed for periods ranging from 387 to 435 days. Two of them were deployed along a major fault linked to a shallow hydrocarbon reservoir while the third monitored the fluid pressure in a pockmark aligned above the same major fault. In addition, 10 ocean‐bottom seismometers (OBS) were deployed for around 60 days. The piezometers simultaneously registered a prolonged fluid flow event lasting 90 days. During this time, OBS measurements record several episodic fluid release events. By combining and analyzing existing and newly acquired data, we show that the fluid‐fault system operates according to the following three stages: (1) upward pore fluid migration through existing conduits and free gas circulation within several shallow sandy layers intersecting the major fault, (2) gas accumulation and pore pressure increases within sandy‐silty layers, and (3) hydrofracturing and fluid pressure dissipation through sporadic degassing events, causing pore fluid circulation through shallow sandy layers and drawing overlying seawater into the sediment. This paper clearly demonstrates how an integrated approach based on seafloor observations, in situ measurements, and monitoring is essential for understanding fault‐fluid‐hydrate systems. Key Points Integrated approach is essential to understanding complex fault‐fluid systems Ocean‐bottom seismometers were able to detect episodic events of fluid release Piezometers were able to detect free‐gas accumulation and hydrofracturing processes
ISSN:0148-0227
2169-9313
2156-2202
2169-9356
DOI:10.1029/2011JB008218