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Geophysical and geochemical evidence of large scale fluid flow within shallow sediments in the eastern Gulf of Mexico, offshore Louisiana

Geophysical and geochemical evidence of large scale fluid flow within shallow sediments in the eastern Gulf of Mexico, offshore Louisiana
Geophysical and geochemical evidence of large scale fluid flow within shallow sediments in the eastern Gulf of Mexico, offshore Louisiana
We analyse the fluid flow regime within sediments on the Eastern levee of the modern Mississippi Canyon using 3D seismic data and downhole logging data acquired at Sites U1322 and U1324 during the 2005 Integrated Ocean Drilling Program (IODP) Expedition 308 in the Gulf of Mexico. Sulphate and methane concentrations in pore water show that sulphate–methane transition zone, at 74 and 94 m below seafloor, are amongst the deepest ever found in a sedimentary basin. This is in part due to a basinward fluid flow in a buried turbiditic channel (Blue Unit, 1000 mbsf), which separates sedimentary compartments located below and above this unit, preventing normal upward methane flux to the seafloor. Overpressure in the lower compartment leads to episodic and focused fluid migration through deep conduits that bypass the upper compartment, forming mud volcanoes at the seabed. This may also favour seawater circulation and we interpret the deep sulphate–methane transition zones as a result of high downward sulphate fluxes coming from seawater that are about 5–10 times above those measured in other basins. The results show that geochemical reactions within shallow sediments are dominated by seawater downwelling in the Mars-Ursa basin, compared to other basins in which the upward fluid flux is controlling methane-related reactions. This has implications for the occurrence of gas hydrates in the subsurface and is evidence of the active connection between buried sediments and the water column.
1468-8115
34-47
Gay, A.
c494a4f5-b9d6-4122-9d47-b3e697e69897
Takano, Y.
bc1a0278-29d9-4ef0-a96f-528b02983dca
Gilhooly III, W.P.
7045ec56-1bdb-4d60-a020-4463797a85a1
Berndt, C.
231544d4-f681-44a2-ae6e-74385e588bf6
Heeschen, K.
a7da037f-19c2-40aa-95a6-e70deaa3de4d
Suzuki, N.
f177438a-f646-4525-99a2-ec323e69bb64
Saegusa, S.
be46c068-ad2c-4883-bbfb-8ee9a168e794
Nakagawa, F.
6abbc04f-0e6f-4551-81f0-091dc0e6b7ce
Tsunogai, U.
36ee3d8e-8b40-4f10-a248-7502372ccce7
Jiang, S.Y.
db520e8d-3fbd-4eb6-b5fe-ae85f429bcc5
Lopez, M.
86a1f90a-7862-480a-bc69-474c5757d39a
Gay, A.
c494a4f5-b9d6-4122-9d47-b3e697e69897
Takano, Y.
bc1a0278-29d9-4ef0-a96f-528b02983dca
Gilhooly III, W.P.
7045ec56-1bdb-4d60-a020-4463797a85a1
Berndt, C.
231544d4-f681-44a2-ae6e-74385e588bf6
Heeschen, K.
a7da037f-19c2-40aa-95a6-e70deaa3de4d
Suzuki, N.
f177438a-f646-4525-99a2-ec323e69bb64
Saegusa, S.
be46c068-ad2c-4883-bbfb-8ee9a168e794
Nakagawa, F.
6abbc04f-0e6f-4551-81f0-091dc0e6b7ce
Tsunogai, U.
36ee3d8e-8b40-4f10-a248-7502372ccce7
Jiang, S.Y.
db520e8d-3fbd-4eb6-b5fe-ae85f429bcc5
Lopez, M.
86a1f90a-7862-480a-bc69-474c5757d39a

Gay, A., Takano, Y., Gilhooly III, W.P., Berndt, C., Heeschen, K., Suzuki, N., Saegusa, S., Nakagawa, F., Tsunogai, U., Jiang, S.Y. and Lopez, M. (2011) Geophysical and geochemical evidence of large scale fluid flow within shallow sediments in the eastern Gulf of Mexico, offshore Louisiana. Geofluids, 11 (1), 34-47. (doi:10.1111/j.1468-8123.2010.00304.x).

Record type: Article

Abstract

We analyse the fluid flow regime within sediments on the Eastern levee of the modern Mississippi Canyon using 3D seismic data and downhole logging data acquired at Sites U1322 and U1324 during the 2005 Integrated Ocean Drilling Program (IODP) Expedition 308 in the Gulf of Mexico. Sulphate and methane concentrations in pore water show that sulphate–methane transition zone, at 74 and 94 m below seafloor, are amongst the deepest ever found in a sedimentary basin. This is in part due to a basinward fluid flow in a buried turbiditic channel (Blue Unit, 1000 mbsf), which separates sedimentary compartments located below and above this unit, preventing normal upward methane flux to the seafloor. Overpressure in the lower compartment leads to episodic and focused fluid migration through deep conduits that bypass the upper compartment, forming mud volcanoes at the seabed. This may also favour seawater circulation and we interpret the deep sulphate–methane transition zones as a result of high downward sulphate fluxes coming from seawater that are about 5–10 times above those measured in other basins. The results show that geochemical reactions within shallow sediments are dominated by seawater downwelling in the Mars-Ursa basin, compared to other basins in which the upward fluid flux is controlling methane-related reactions. This has implications for the occurrence of gas hydrates in the subsurface and is evidence of the active connection between buried sediments and the water column.

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Published date: February 2011
Additional Information: Early View
Organisations: Marine Geoscience

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Local EPrints ID: 172241
URI: http://eprints.soton.ac.uk/id/eprint/172241
ISSN: 1468-8115
PURE UUID: 37eae96d-7f1d-4072-89bf-81a686f55b33

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Date deposited: 24 Jan 2011 14:59
Last modified: 14 Mar 2024 02:28

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Contributors

Author: A. Gay
Author: Y. Takano
Author: W.P. Gilhooly III
Author: C. Berndt
Author: K. Heeschen
Author: N. Suzuki
Author: S. Saegusa
Author: F. Nakagawa
Author: U. Tsunogai
Author: S.Y. Jiang
Author: M. Lopez

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