Proc. IODP, 322, Methods

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Expedition reports Research results Supplementary material Drilling maps Expedition bibliography
Chapter contents Introduction Site locations Drilling operations Drilling-induced core deformation Numbering of sites, holes, cores, sections, and samples Core handling Authorship of chapters X-ray computed tomography Background X-ray CT scan data usage Lithology Visual core descriptions Smear slides and thin sections X-ray diffraction X-ray fluorescence X-ray fluorescence scanning Basement description Structural geology Core description and orientation data collection Orientation data analysis based on the spreadsheet J-CORES structural database Description and classification of structures Biostratigraphy Calcareous nannofossils Planktonic foraminifers Paleomagnetism Laboratory instruments Discrete samples and sampling coordinates Orientation of discrete samples Paleomagnetic reorientation of cores Magnetic reversal stratigraphy Data reduction and software Physical properties MSCL-W MSCL-I: photo image logger MSCL-C: color spectroscopy logger Moisture and density measurements Shear strength measurements Anisotropy of P-wave velocity and electrical resistivity Thermal conductivity Inorganic geochemistry Interstitial water collection Correction for drilling contamination Interstitial water analysis Organic geochemistry Hydrocarbon gases Hydrogen gas Total carbon, nitrogen, and sulfur contents of the solid phase Inorganic carbon, organic carbon, and carbonate content of the solid phase Characterization of the type and maturity of organic matter by Rock-Eval pyrolysis Microbiology Whole-round core sampling and handling Sample processing for cell detection by epifluorescence microscopy Routine microbiology samples Evaluation of potential contamination Downhole measurements In situ pressure and temperature measurements Logging and core-log-seismic integration Logging while drilling Wireline logging Log characterization and interpretation Core-Log-Seismic integration References Figures F1. IODP naming conventions. F2. Standard core flow. F3. Graphic patterns for sedimentary lithologies. F4. Diagnostic X-ray diffraction peaks. F5. Graphic patterns for basement lithologies. F6. Structural data log sheet. F7. Modified protractor. F8. Core coordinate system. F9. Orientation data spreadsheet. F10. Plane orientation from apparent dips. F11. Dip direction, right-hand rule strike, and dip. F12. Apparent rake measurement of slickenlines. F13. Rake of slickenlines. F14. Azimuth correction based on paleomagnetic data. F15. GPTS, biostratigraphic zonation, and biohorizon correlation. F16. Orientation system. F17. Axis orientation on working-half sections. F18. Subsampling 5 cm whole-round cores. F19. LWD/MWD tool string and geoVISION tool. F20. Shipboard structure and data flow. Tables T1. X-ray CT scanner settings. T2. Volcanic lithology classification. T3. Smear slide component categories. T4. XRD peaks. T5. Bulk powder XRD normalization factors. T6. XRF quantitative conditions. T7. Continuous measurement results. T8. Volcanic basement lithology classification. T9. Calcareous nannofossil datum ages. T10. Planktonic foraminifer datum ages. T11. GPTS ages. T12. Shipboard and shore-based chemical analyses. T13. Interstitial water squeeze cake distribution. T14. geoVISION tool specifications. T15. Wireline logging tool specifications. T16. Core-log-seismic integration. PDF file			Previous \| Next doi:10.2204/iodp.proc.322.102.2010 References Aguirre, E., and Pasini, G., 1985. The Pliocene–Pleistocene boundary. Episodes, 8:11–120. Amann, R.I., and Fuchs, B.M., 2008. Single-cell identification in microbial communities by improved fluorescence in situ hybridization techniques. Nat. Rev. Microbiol., 6(5):339–348. doi:10.1038/nrmicro1888 ASTM International, 1990. Standard method for laboratory determination of water (moisture) content of soil and rock (Standard D2216–90). In Annual Book of ASTM Standards for Soil and Rock (Vol. 04.08): Philadelphia (Am. Soc. 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