Proc. IODP, 317, Expedition 317 summary

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Chapter contents Abstract Introduction Geologic setting Regional geology Site survey data and interpretation Data acquisition Seismic stratigraphy Sediment drifts and paleoflow Scientific objectives Primary objective Secondary objectives Operational strategy Drilling transect strategy General operations plan Traveltime/depth conversion Synopsis Core-seismic correlation Sedimentary cyclicity Sedimentary processes Marshall Paraconformity Biostratigraphy Age-depth plots Porosity and backstripping Geochemistry Microbiology Preliminary scientific assessment Site summaries Site U1351 Site U1352 Site U1353 Site U1354 References Figures F1. Map of Canterbury Basin. F2. Bathymetric map of Canterbury Basin. F3. Expedition 317 sites. F4. Schematic stratigraphy of Canterbury Basin. F5. Subsidence curves and paleodepths for Clipper well. F6. Revised subsidence analysis for Clipper well. F7. MCS profile of Sites U1351, U1353, and U1354. F8. Seismic Profile EW00-01-12 across slope. F9. Seismic Profile EW00-01-60 across slope. F10. Comparison of commercial and high-resolution MCS profiles. F11. Seismic sequence boundary age estimates and tentative correlation. F12. Correlation of U1–U14 with sediment drifts and oxygen isotopic record. F13. Lithologic units at shelf sites correlated to seismic profile. F14. Lithologic units at slope site correlated to seismic profile. F15. Summary of lithology and unit boundaries. F16. Carbonate estimates. F17. Core recovery summary. F18. Calcium carbonate, Holes U1352B and 1119C. F19. Lithologic contacts and correlation. F20. Lithologic contacts and correlative seismic sequence boundaries across shelf. F21. Holocene–Pleistocene correlation at shelf sites. F22. Chronostratigraphic framework for predicted seismic sequence boundaries. F23. Magnetic susceptibility. F24. Lithology, color data, and magnetic susceptibility. F25. Gamma ray and electrical resistivity data. F26. Oceanicity variations. F27. Paleowater depth variations. F28. Age-depth plot, Hole U1353B. F29. Age-depth plot, Holes U1354A–U1354C. F30. Age-depth plot, Hole U1351B. F31. Age-depth plot, Holes U1352B and U1352C. F32. Porosity. F33. Methane, alkalinity, sulfate, and phosphate. F34. Calcium, magnesium, sodium, and potassium. F35. Carbonate, TOC_DIFF, TOC_DIFF/TN, T_max, HI, and PI. Tables T1. Coring summary, Expedition 317. T2. Sequences drilled during Expedition 317. PDF file			Previous \| Next doi:10.2204/iodp.proc.317.101.2011 Expedition 317 summary¹ Expedition 317 Scientists² Abstract Integrated Ocean Drilling Program (IODP) Expedition 317 was devoted to understanding the relative importance of global sea level (eustasy) versus local tectonic and sedimentary processes in controlling continental margin sedimentary cycles. The expedition recovered sediments from the Eocene to recent period, with a particular focus on the sequence stratigraphy of the late Miocene to recent, when global sea level change was dominated by glacioeustasy. Drilling in the Canterbury Basin, on the eastern margin of the South Island of New Zealand, takes advantage of high rates of Neogene sediment supply, which preserves a high-frequency (0.1–0.5 m.y.) record of depositional cyclicity. Because of its proximity to an uplifting mountain chain (the Southern Alps) and strong ocean currents, the Canterbury Basin provides an opportunity to study the complex interactions between processes responsible for the preserved sequence stratigraphic record. Currents have locally built large, elongate sediment drifts within the prograding Neogene section. These elongate drifts were not drilled during Expedition 317, but currents are inferred to have strongly influenced deposition across the basin, including locations lacking prominent mounded drifts. Upper Miocene to recent sedimentary sequences were cored in a transect of three sites on the continental shelf (landward to basinward, Sites U1353, U1354, and U1351) and one on the continental slope (Site U1352). The transect provides a stratigraphic record of depositional cycles across the shallow-water environment most directly affected by relative sea level change. Lithologic boundaries provisionally correlative with seismic sequence boundaries were identified in cores from each site, providing insight into the origins of seismically resolvable sequences. This record will be used to estimate the timing and amplitude of global sea level change and to document the sedimentary processes that operate during sequence formation. Sites U1353 and U1354 provide significant double-cored, high-recovery sections through the Holocene, allowing for high-resolution study of recent glacial cycles in a continental shelf setting. Continental slope Site U1352 represents a complete section from modern slope terrigenous sediment to hard Eocene limestone, with all the associated lithologic, biostratigraphic, physical, geochemical, and microbiological transitions. This site also provides a record of ocean circulation and fronts during the last ~35 m.y. The early Oligocene (~30 Ma) Marshall Paraconformity was the deepest drilling target of Expedition 317 and was hypothesized to represent intensified current erosion or nondeposition associated with the initiation of thermohaline circulation following the separation of Australia and Antarctica. Expedition 317 set a number of scientific ocean drilling records: (1) deepest hole drilled in a single expedition and second deepest hole in the history of scientific ocean drilling (Hole U1352C, 1927 m); (2) deepest hole and second deepest hole drilled by the R/V JOIDES Resolution on a continental shelf (Hole U1351B, 1030 m; Hole U1353B, 614 m); (3) shallowest water depth for a site drilled by the JOIDES Resolution for scientific purposes (Site U1353, 84.7 m water depth); and (4) deepest sample taken during scientific ocean drilling for microbiological studies (Site U1352, 1925 m). Expedition 317 supplements previous drilling of sedimentary successions for sequence stratigraphic and sea level objectives, particularly drilling on the New Jersey margin (Ocean Drilling Program [ODP] Legs 150, 150X, 174A, and 174AX and IODP Expedition 313) and in the Bahamas (ODP Leg 166), but includes an expanded Pliocene section. Completion of at least one transect across a geographically and tectonically distinct siliciclastic margin was the necessary next step in deciphering continental margin stratigraphy. Expedition 317 also complements ODP Leg 181, the focus of which was drift development in more distal parts of the Eastern New Zealand Oceanic Sedimentary System (ENZOSS). ¹Expedition 317 Scientists, 2011. Expedition 317 summary. In Fulthorpe, C.S., Hoyanagi, K., Blum, P., and the Expedition 317 Scientists, Proc. IODP, 317: Tokyo (Integrated Ocean Drilling Program Management International, Inc.). doi:10.2204/iodp.proc.317.101.2011 ²Expedition 317 Scientists' addresses. Publication: 4 January 2011 MS 317-101 Top of page \| Previous \| Next