Expedition UT-GOM2-2 Site H
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- Univ. of Texas, Austin, TX (United States)
- US Geological Survey, Reston, VA (United States)
- The Ohio State Univ., Columbus, OH (United States)
- Univ. of Washington, Seattle, WA (United States)
- Oregon State Univ., Corvallis, OR (United States)
- Univ. of New Hampshire, Durham, NH (United States)
- ExxonMobil, Houston, TX (United States)
- Colorado School of Mines, Golden, CO (United States)
- Tufts Univ., Medford, MA (United States)
- Geotek Ltd., Daventry (United Kingdom)
- Geotek Coring Inc., Salt Lake City, UT (United States)
- Japan Agency for Marine-Earth Science and Technology, Yokohama (Japan)
- Pettigrew Engineering, PLLC, Milam, TX (United States)
- TR Consulting (United States)
Pressure and conventional cores were collected at Site H of the Walker Ridge Protracted Area Block 313 in the Terrebonne Basin, deepwater Gulf of America (Gulf of Mexico) during the University of Texas (UT) Deepwater Hydrate Coring Expedition (UT-GOM2-2). Pressure and conventional cores were collected continuously to a depth of 155.1 meters below the seafloor (mbsf). At deeper depths, cores were taken periodically from hydrate-bearing sands and their bounding muds to a total depth of 861.3 mbsf. 162.6 m of conventional core and 54.8 m of pressure core were recovered. Twelve temperature measurements were made between 27.1 and 144.5 mbsf to determine the geothermal gradient. At the seafloor, more than 4 m of sandy silt of unknown origin was encountered. Beneath this sand, to a depth of about 200 mbsf, the section was composed of interbedded mud and biogenic carbonate ooze. The ooze correlated to low density and high porosity intervals observed in the previously acquired logging while drilling (LWD) data and as measured. These ooze intervals also correspond to lighter sediment color, increased Ca content based on X-ray florescence (XRF) core scanning, and increased calcareous nannofossil abundance. Calcareous nannofossil biostratigraphy constrains the entire record to the Pleistocene (< 0.91 million years), with a pronounced increase in sedimentation rate with depth. Below 200 mbsf, the section was predominantly composed of mud with two thicker, hydrate-bearing coarse-grained intervals, which are commonly known as the Blue and Orange sands. The dissolved gas concentration was quantified from pressure cores. In the shallow section, dissolved methane concentration increased below the sulfate-methane transition zone (SMTZ) and reaches saturation (the limit of solubility for methane) at 147 mbsf. Gas expansion was very common in conventional and depressurized pressure (conventionalized) cores below the SMTZ. At deeper depths, the methane concentration within muds bounding the Blue and Orange reservoirs was generally found to be less than saturation. The dissolved and hydrate gas composition is consistent with a microbial source, containing greater than 99.99% methane and only trace concentrations of ethane, propane, and butane. The methane to ethane ratio (C1 /C2 ) and the methane to ethane plus propane (C1 /(C2 +C3 )) decrease with depth down to at least 678 mbsf, mainly driven by the increase in ethane with depth. It is unclear if this trend continues through the Orange sand interval. The δ13C isotopic signature of methane ranges between -69.9 and -78.5 ‰ relative to the Vienna Pee Dee Belemnite (VPDB) standard. Pressure core recovery in sandy intervals was poor. However, pressure core logs of the Orange sand show intervals of low density and high velocity, which are indicative of high hydrate saturation. One pressure core was degassed and the average hydrate saturation in the core was determined to be 24%. One core from within the Orange sand was composed of interbedded graded sandy silt and mud. The sandy silts from this core are composed of mainly quartz and feldspar with some lithics. Most of the recovered pressure core samples are maintained at near in-situ pressure and temperature (within the hydrate stability field) at the University of Texas Pressure Core Center awaiting analysis. In the shallow section, samples will be used to determine the flux of organic carbon through the basin system, find the rate at which that carbon was consumed, and understand the microbial population responsible for these processes. In the deeper section, samples from in and around the hydrate reservoirs will be used to determine the petrophysical properties of the reservoir and bounding seals in these systems.
- Research Organization:
- Univ. of Texas, Austin, TX (United States); US Geological Survey, Reston, VA (United States); The Ohio State Univ., Columbus, OH (United States); Univ. of New Hampshire, Durham, NH (United States); Univ. of Washington, Seattle, WA (United States); Oregon State Univ., Corvallis, OR (United States); Tufts Univ., Medford, MA (United States); Colorado School of Mines, Golden, CO (United States); Geotek Ltd., Daventry (United Kingdom); Geotek Coring Inc., Salt Lake City, UT (United States); Us Department of the Interior, Washington, DC (United States). Bureau of Ocean Energy Management; National Energy Technology Laboratory (NETL), Pittsburgh, PA, Morgantown, WV, and Albany, OR (United States)
- Sponsoring Organization:
- USDOE Office of Fossil Energy and Carbon Management (FECM)
- DOE Contract Number:
- FE0023919
- OSTI ID:
- 2584167
- Report Number(s):
- DOE-UT--0023919-UTGOM2-2-005; UT-GOM2-2
- Country of Publication:
- United States
- Language:
- English
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OSTI ID:2439982