Proc. IODP, 347, Site M0063

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Chapter contents Introduction Operations Transit to Hole M0062A Hole M0063A Hole M0063B Hole M0063C Hole M0063D Hole M0063E Lithostratigraphy Unit I Unit II Unit III Unit IV Unit V Unit VI Unit VII Biostratigraphy Diatoms Foraminifers Ostracods Palynological results Geochemistry Interstitial water Sediment Physical properties Natural gamma radiation Magnetic susceptibility and noncontact resistivity Density P-wave velocity Paleomagnetism Discrete sample measurements Magnetic susceptibility Natural remanent magnetization and its stability Paleomagnetic directions Microbiology Stratigraphic correlation Seismic units Downhole measurements Logging operations Logging units References Figures F1. Graphic lithology log. F2. Lithostratigraphic units. F3. Carbonate concretion. F4. Transverse faults. F5. Diatom taxa, Hole M0063A. F6. Diatom taxa, Hole M0063E. F7. Benthic foraminifers. F8. Ostracods. F9. Palynomorphs. F10. Pollen diagram. F11. Simplified pollen diagram. F12. Chloride, salinity, and alkalinity. F13. Methane, sulfate, sulfide, ammonium, phosphate, iron, manganese, and pH. F14. Bromide, boron, and chloride. F15. Sodium, potassium, magnesium, calcium, and chloride. F16. Strontium, lithium, silica, and barium. F17. TC, TOC, TIC, and TS. F18. NGR, MS, NCR, and dry density. F19. Gamma and discrete bulk density, P-wave velocity. F20. Gamma and discrete bulk density. F21. MS and NRM. F22. NRM. F23. Microbial cell abundances. F24. Sediment. F25. Two methods of cell enumeration. F26. PFC tracer concentrations. F27. Coring disturbances. F28. Downhole and natural gamma ray. F29. Seismic profile and lithostratigraphic boundaries. F30. Caliper, gamma ray, spectral gamma ray, resistivity, and sonic logs. Tables T1. Operations. T2. Diatoms, Hole M0063A. T3. Diatoms, Hole M0063C. T4. Diatoms, Hole M0063E. T5. Diatom species. T6. Foraminifers. T7. Ostracods. T8. Interstitial water geochemistry. T9. Salinities and elemental ratios. T10. Methane. T11. TC, TOC, TIC, and TS. T12. Cell counts. T13. Drilling fluid contamination. T14. Composite depth scale. T15. Sound velocity. PDF file			Previous \| Next doi:10.2204/iodp.proc.347.107.2015 References Andrén, E., Andrén, T., and Kunzendorf, H., 2000a. Holocene history of the Baltic Sea as a background for assessing records of human impact in the sediments of the Gotland Basin. Holocene, 10(6):687–702. doi:10.1191/09596830094944 Andrén, E., Andrén, T., and Sohlenius, G., 2000b. The Holocene history of the southwestern Baltic Sea as reflected in a sediment core from the Bornholm Basin. Boreas, 29(3):233–250. doi:10.1111/j.1502-3885.2000.tb00981.x Andrén, T., Björck, S., Andrén, E., Conley, D., Zillén, L., and Anjar, J. 2011. The development of the Baltic Sea Basin during the last 130 ka. In Harff, J., Björck, S., and Hoth, P. 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