Proc. IODP, 311, Site U1327

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Chapter contents Background and objectives Seismostratigraphy at Site 889 Bottom-simulating reflector occurrence Previous gas hydrate concentration estimates Objectives Operations Hole U1327A Hole U1327B Hole U1327C Hole U1327D Hole U1327E Lithostratigraphy Lithostratigraphic units Environment of deposition Biostratigraphy Diatoms Interstitial water geochemistry Salinity and chlorinity Biogeochemical processes Deep-seated fluid Organic geochemistry Hydrocarbons Biogeochemical processes Sediment carbon and nitrogen composition Microbiology Microbiological sampling Contamination tests Shipboard analysis Physical properties Infrared images Sediment density and porosity Magnetic susceptibility Compressional wave velocity from the multisensor track and Hamilton frame Shear strength Electrical resistivity Thermal conductivity In situ temperature profile Paleomagnetism Pressure coring Operation of pressure coring systems Degassing experiments Measurements on HYACINTH cores Gas hydrate concentration, nature, and distribution Downhole logging Logging while drilling Wireline logging Logging-while-drilling and wireline logging comparison Logging units Logging-while-drilling borehole images Logging porosities Gas hydrate and free gas occurrence Vertical seismic profile Differences in resistivity logs, instrumental effects, and lateral heterogeneity Temperature data References Figures F1. Seafloor bathymetry. F2. Reflection coefficient. F3. Subbottom profiler data. F4. Site 889 data. F5. MCS Line 89-08. F6. MCS Inline 38. F7. MCS Xline 3. F8. BSR reflection coefficient. F9. Site U1327 hole locations. F10. Lithostratigraphic summary. F11. Dark gray silty clay with sandy silt. F12. Dark gray silty clay with sand. F13. Dark gray silty clay with rock. F14. XRD record. F15. Unlithified carbonate. F16. Soft-sediment deformation. F17. Rock pebbles. F18. Soupy and mousselike sediment texture. F19. Biscuit structure. F20. XRD record. F21. Pressure core. F22. Salinity, Cl, Na, and K. F23. Alkalinity, sulfate, ammonium, and phosphate. F24. Ca, Mg, and Sr and Mg/Ca. F25. Sulfate. F26. Si, Li, and B. F27. Methane and ethane. F28. Ethane, propane, i-butane, and n-butane. F29. Methane/ethane. F30. Methane/ethane and i-butane/n-butane. F31. Methane/ethane vs. temperature. F32. Sulfate and methane. F33. Carbon content and C/N ratios. F34. Physical property data. F35. IR images. F36. Downhole and core liner temperatures. F37. IR images and temperature profiles. F38. Downhole plot. F39. Magnetic susceptibility. F40. P-wave velocity. F41. Shear strength. F42. Pore water resistivity. F43. Thermal conductivity. F44. Temperature and pressure. F45. Temperature measurements. F46. Paleomagnetic data. F47. Temperature and pressure vs. time. F48. Temperature vs. pressure. F49. Methane phase diagram. F50. Pressure vs. volume. F51. Depth-dependent data. F52. Pressure core data. F53. Gamma ray density vs. velocity. F54. LWD/MWD logs. F55. LWD data. F56. Wireline logging data summary. F57. DSI tool data. F58. LWD and wireline data. F59. Wireline logging data. F60. LWD image data. F61. LWD porosity logs. F62. Water saturation. F63. WST data. F64. Time vs. depth. F65. VSP and P-wave velocity. F66. Gas hydrate distribution. F67. Borehole temperatures. Tables T1. Coring summary. T2. Diatoms. T3. IW solutes. T4. Corrected IW solutes. T5. Headspace gas. T6. Void gas. T7. PCS gas. T8. Carbon. T9. Contamination testing. T10. Moisture and density. T11. Density gradients. T12. Compressional wave velocity. T13. Torvane shear strength. T14. AVS shear strength. T15. Contact resistivity. T16. Thermal conductivity. T17. In situ temperature. T18. Pressure coring operations. T19. PCS core conditions. T20. Degassing experiment results. T21. PCS core characteristics. T22. Mass balance calculations. T23. Parr vessel Samples T24. VSP data. PDF file Errata		Previous \| Next doi:10.2204/iodp.proc.311.105.2006 References Aldred, W., Cook, J., Bern, P., Carpenter, B., Hutchinson, M., Lovell, J., Rezmer-Cooper, I., and Leder, P.C., 1998. Using downhole annular pressure measurements to improve drilling performance. Oilfield Rev., 10(4):40–55. Appenzeller, T., 1991. Fire and ice under the deep sea floor. Science, 252:1790–1792. Boetius, A., Ravenschlag, K., Schubert, C.J., Rickert, D., Widdel, F., Gieseke, A., Amann, R., Jørgensen, B.B., Witte, U., and Pfannkuche, O., 2000. 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