Proc. IODP, 317, Site U1351

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Chapter contents Background and objectives Hole U1351A Hole U1351B Hole U1351C Operations Transit to Site U1351 Site U1351 overview Hole U1351A Hole U1351B Hole U1351C Lithostratigraphy Description of lithologic units Downhole trends in sediment composition and mineralogy Correlation with wireline logs Description of lithologic surfaces and associated sediment facies Discussion and interpretation Biostratigraphy Calcareous nannofossils Planktonic foraminifers Benthic foraminifers Paleowater depths Diatoms Macrofossils Paleomagnetism Section-half measurements Discrete measurements Magnetostratigraphy Physical properties Gamma ray attenuation bulk density Magnetic susceptibility Natural gamma radiation P-wave velocities Spectrophotometry and colorimetry Moisture and density Sediment strength Geochemistry and microbiology Organic geochemistry Inorganic geochemistry Microbiology Heat flow Geothermal gradient Thermal conductivity Bullard plot Downhole logging Operations Data quality Logging stratigraphy Core-log correlation Stratigraphic correlation References Figures F1. Seismic dip profile. F2. Drilled and proposed sites. F3. Lithologic summary, Hole U1351B. F4. Core recovery and lithology. F5. Unit I/II boundary options. F6. Lithostratigraphic correlation between Holes U1351A and U1351B. F7. Correlative intervals and lithologic surfaces. F8. Slumped deposit. F9. Biscuiting structures. F10. Downhole cave-in. F11. Unit I lithologies at U1351A-S1. F12. Unit I lithologies associated with U1351B-S2 and U1351B-S6. F13. Unit I lithologies. F14. Smear slide mineralogy. F15. Glauconitic limestone beds. F16. Summary of shipboard analyses, Hole U1351B. F17. Unit I facies assemblage model. F18. Downhole gamma ray summary. F19. Logging data, Holes U1351B and U1351C. F20. Unit II lithologies. F21. Induration and cementation. F22. XRD peak intensities for common minerals. F23. Mineral concentration estimates. F24. Planktonic and benthic foraminifer correlation. F25. Planktonic foraminiferal abundance. F26. Sparry calcite and glauconite-infilled benthic foraminifers. F27. Benthic foraminifer paleodepth interpretation. F28. NRM paleomagnetic record, Hole U1351B. F29. NRM paleomagnetic record for 0–100 m, Hole U1351B. F30. NRM paleomagnetic record for 110–275 m, Hole U1351B. F31. IRM, backfield acquisition curves, and AF demagnetization of IRM. F32. Raw MS, NGR, GRA bulk density, and b. F33. Filtered MS, NGR, GRA bulk density, and b. F34. Bulk density comparison. F35. Bulk density and porosity comparison. F36. Bulk density variation with caliper width. F37. Raw MS, NGR, GRA bulk density, and b* for top 180 m of Hole U1351B. F38. Filtered MS, NGR, GRA bulk density, and b* for top 180 m of Hole U1351B. F39. NGR for youngest climatic cycle in Hole U1351B. F40. P-wave velocities. F41. MS and colorimetry data, Hole U1351B. F42. MS and colorimetry data for top 80 m of Hole U1351B. F43. Bulk density, grain density, porosity, and void ratio. F44. Porosity variation with caliper width. F45. Sediment strength data. F46. Gas concentrations and composition. F47. Core void gases. F48. Carbon variation. F49. Sediment elemental concentrations. F50. SRA data. F51. SRA parameters. F52. Cross-plot of HI and OI showing kerogen types. F53. Cross-plot of CHNS and SRA carbon. F54. Total carbonate content vs. TOC_SRA. F55. Chloride and salinity. F56. Sr, Sr/Ca, pH, Ca, Mg, and Mg/Ca. F57. Alkalinity and sulfate. F58. Phosphate, silica, ammonium, and silicon. F59. Li, Na, K, Ba, and B. F60. Geochem profiles through SMT. F61. Geochem profiles through diagenetic zone. F62. Total prokaryotic cells. F63. Temperature data. F64. Thermal conductivity vs. depth, porosity, and bulk density. F65. Thermal resistance Bullard plot. F66. Triple combo log summary vs. physical property data. F67. FMS-sonic log summary. F68. Downhole gamma ray vs. NGR. F69. FMS images and associated core photographs. Tables T1. Coring summary. T2. Lithostratigraphic summary. T3. Cemented intervals. T4. Lithologic surfaces. T5. Lithostratigraphic correlation. T6. Microfossil bioevents. T7. Calcareous nannofossils. T8. Planktonic foraminifers, Hole U1351A. T9. Planktonic foraminifers, Hole U1351B. T10. Planktonic foraminiferal summary, Hole U1351A. T11. Planktonic foraminiferal summary, Hole U1351B. T12. Benthic foraminifers. T13. Diatoms. T14. Invertebrate macrofossils. T15. Headspace gas composition. T16. Core void gas composition. T17. Carbon, nitrogen, and sulfur analyses. T18. SRA organic matter pyrolysis. T19. Salinity, pH, alkalinity, and ion chromatograph data. T20. Spectrophotometry and ICP-AES data. T21. Mass balance in sulfate reduction zone. T22. Sediment sample contamination. T23. Temperature data. T24. Thermal conductivity data. PDF file			Previous \| Next doi:10.2204/iodp.proc.317.103.2011 References Abbott, S.T., and Carter, R.M., 1999. Stratigraphy of the Castlecliffian type section: 10 mid-Pleistocene sequences from the Wanganui coast, New Zealand. N. Z. J. Geol. 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