Proc. IODP, 308, Expedition 308 summary

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Chapter contents Abstract Introduction Geological overview: Gulf of Mexico Geological setting Scientific objectives Operational strategy Site results Site U1319 Site U1320 Site U1321 Site U1322 Site U1323 Site U1324 Discussion and conclusions Challenges of drilling in overpressured basins Challenges of measuring pressure Synthesis of Brazos-Trinity Basin IV geology Synthesis of Ursa Basin geology Physical properties in Brazos-Trinity IV and Ursa Basins Geochemical indicators of fluid flow Preliminary interpretation of overpressure and hydrodynamics in Ursa Basin Overview of expedition achievements and preliminary scientific assessment Original objectives Additional achievements References Figures F1. Sedimentation overpressure. F2. Flow-focusing model. F3. Flow focusing. F4. Bathymetry of Gulf of Mexico. F5. Bathymetry of Brazos-Trinity Basin IV. F6. Dip Section 3020. F7. Strike Line 3045. F8. Bathymetry, Ursa Basin. F9. Basemap Section A-A'. F10. NGR, porosity, pressure. F11. Seismic cross section. F12. T2P probe. F13. Site U1319 measurements. F14. Site U1320 measurements. F15. Site U1321 measurements. F16. Site U1322 measurements. F17. Site U1323 measurements. F18. Site U1324 measurements. F19. Barite supplies. F20. Pressure vs. depth. F21. MWD results, Site U1323. F22. T2P and DVTPP. F23. DVTPP and T2P deployments. F24. DVTPP and T2P deployment breakdown. F25. Probe deployment procedure. F26. Dip seismic line RING logs. F27. Strike seismic line RING logs. F28. Brazos-Trinity age model. F29. Stratigraphy of Brazos-Trinity Basin. F30. Facies in each unit. F31. Ursa Basin site correlation. F32. Ursa Basin age constraints. F33. Ursa Basin seismic data. F34. MTD diagnostic features. F35. Porosity, Brazos-Trinity Basin. F36. Void ratio vs. hydrostatic effective stress, Brazos-Trinity Basin. F37. Porosity, Sites U1322–U1324. F38. Void ratio vs. hydrostatic effective stress, Site U1324. F39. LWD porosity. F40. Pore water geochemistry, Brazos-Trinity Basin IV. F41. Pore water geochemistry, Ursa Basin. F42. Porosity, Ursa Basin. F43. Porosity-based pressure prediction. F44. DVTPP/T2P data. F45. Downhole temperature data. F46. Temperature/pressure gradient. Tables T1. Heavy mud used while coring and drilling. T2. Expedition 308 operations summary. PDF file			Previous \| Next doi:10.2204/iodp.proc.308.101.2006 Scientific objectives The six scientific objectives of Expedition 308 are described below. 1. Document how pressure, stress, and geology couple to control fluid migration on passive margins. We hypothesized that flow-focusing is present in Ursa Basin (Figs. F2, F3). This should result in a characteristic spatial distribution of fluid pressure and rock properties (e.g., consolidation, permeability, and shear strength) in the mud overlying the Blue Unit. Our objective was to measure fluid pressure and rock properties through downhole tools, core, and logs to establish the vertical and lateral variation in pressure and rock properties above the Blue Unit. These data would test and refine the flow-focusing model. 2. Establish reference properties at Brazos-Trinity Basin IV sites. We wished to establish reference logging and core properties where overpressure is hypothesized to be zero and thus to measure properties at a range of effective stresses. These data would serve as a baseline against which the properties measured in Ursa Basin could be compared, allowing us to establish the deviation in sediment and fluid properties caused by fluid overpressure and low effective stress. 3. Illuminate the controls on slope stability. Numerous mass transport deposits are present in Ursa Basin. We wished to determine pore pressure, rock properties, and overburden stress to predict the potential for mass transport deposits in the future and to estimate the conditions that drove previous mass transport deposits. 4. Understand rates of sedimentation and timing of mass transport deposits. Sedimentation rate drives the generation of overpressure. However, the age of strata in Ursa Basin is poorly understood. We wished to establish an age model to estimate the sedimentation rate and the timing of MTDs. 5. Establish geotechnical and petrophysical properties of shallow sediments. We wished to understand the state and evolution of geotechnical and petrophysical properties of mud at effective stresses encountered between the seafloor and 500 mbsf. A complete logging suite, in situ measurements of permeability and pressure, and core samples will allow us to understand compaction and flow processes near the seafloor. 6. Provide an extraordinary data set to observe ponded and channelized turbidite systems. Brazos-Trinity Basin IV and Ursa Basin are foci of study for turbidite depositional systems. Logging and core data will provide a good opportunity to study turbidite depositional systems and related MTDs. Top of page \| Previous \| Next