Proc. IODP, 333, Site C0018

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Chapter contents Background and objectives Operations Lithology Subunit IA (slope-basin facies) Subunit IB (sand-rich slope basin) X-ray fluorescence analyses Structural geology Structural elements above MTD 6 (within lithologic Subunit IA) Structural elements within MTD 6 (127.545–188.573 mbsf) Structural elements below MTD 6 (lithologic Subunit IB) Biostratigraphy Paleomagnetism Natural remanent magnetization and magnetic susceptibility Magnetostratigraphy Physical properties MSCL-W Moisture and density measurements Strength measurements Electrical resistivity Thermal conductivity and heat flow Inorganic geochemistry Fluid recovery Salinity, chlorinity, and sodium Biogeochemical processes Organic geochemistry Hydrocarbon gas Sediment carbon, nitrogen, and sulfur composition Rock-Eval pyrolysis References Figures F1. Detailed bathymetry. F2. Bathymetric map. F3. Schematic sedimentary log. F4. Relative occurrence and thickness of ash and sand. F5. XRD data. F6. Top of MTD 2. F7. Shear zone at base of MTD 2. F8. Fluidized ash layer, MTD 4. F9. Internal deformation within MTD 6. F10. Fining-upward trends. F11. X-ray fluorescence major elements. F12. Bedding dip angles and deformation structure distribution. F13. Equal area projection of poles to bedding. F14. Faults, Subunit IA. F15. Equal area projection of poles to fault. F16. Slump fold. F17. Equal area projection of poles to folded bedding plane. F18. Shear zone. F19. Flow structure. F20. Fault with slickenlines and steps. F21. Web structures. F22. Equal area projection of poles to bedding and fissility. F23. Fissility in siltstone. F24. Age-depth plot. F25. Magnetic susceptibility and remanent magnetization. F26. AF demagnetization results. F27. Inclinations after 30 mT demagnetization. F28. Variation of declinations. F29. Magnetic inclination, inferred polarity, and tephra chronological age. F30. MSCL-W measurements. F31. MAD measurements. F32. Penetrometer and vane shear strength. F33. Measured resistivity. F34. Thermal conductivity. F35. APCT-3 temperatures. F36. Projected temperatures. F37. Interstitial water, dissolved sulfate, and percent contamination. F38. Interstitial water constituents. F39. More interstitial water constituents. F40. Interstitial water trace element constituents. F41. Methane and ethane concentrations. F42. CaCO₃, TOC, TN, TOC/TN_at, and TS. F43. Rock-Eval pyrolysis parameters. Tables T1. Coring summary. T2. MTD interval summary. T3. Bulk powder XRD results. T4. Detailed MTD intervals. T5. XRF results. T6. Calcareous nannofossil range chart. T7. Calcareous nannofossil events. T8. Paleomagnetic age datums. T9. Moisture and density results. T10. Electrical resistivity. T11. Raw interstitial water geochemistry. T12. Corrected interstitial water geochemistry. T13. Headspace methane and ethane concentration. T14. CaCO₃, TOC, TN, TOC/TN_at, and TS. T15. Rock-Eval pyrolysis. PDF file			Previous \| Next doi:10.2204/iodp.proc.333.103.2012 References Bouma, A.H., 1962. Sedimentology of Some Flysch Deposits: A Graphic Approach to Facies Interpretation: Amsterdam (Elsevier). Conin, M., Henry, P., Bourlange, S., Raimbourg, H., and Reuschlé, T., 2011. Interpretation of porosity and LWD resistivity from the Nankai accretionary wedge in light of clay physicochemical properties: evidence for erosion and local overpressuring. Geochem., Geophys., Geosyst., 12:Q0AD07. doi:10.1029/2010GC003381 Espitalié, J., Laporte, J.L., Madec, M., Marquis, F., Leplat, P., Paulet, J., and Boutefeu, A., 1977. Méthode rapide de caractérisation des roches mètres, de leur potentiel pétrolier et de leur degré d’évolution. Rev. Inst. Fr. Pet., 32(1):23–42. doi:10.2516/ogst:1977002 Espitalié, J., Senga Makadi, K., and Trichet, J., 1985. Role of the mineral matrix during kerogen pyrolysis. In Schenck, P.A. (Ed.), Advances in Organic Geochemistry 1983: Oxford (Pergamon Press). 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