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IODP Town Hall Meeting 2004 Fall AGU Meeting San Francisco, CA 14 December 2004 IODP Town Hall Meeting 2004 Fall AGU Meeting San Francisco, CA 14 December.

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Presentation on theme: "IODP Town Hall Meeting 2004 Fall AGU Meeting San Francisco, CA 14 December 2004 IODP Town Hall Meeting 2004 Fall AGU Meeting San Francisco, CA 14 December."— Presentation transcript:

1 IODP Town Hall Meeting 2004 Fall AGU Meeting San Francisco, CA 14 December 2004 IODP Town Hall Meeting 2004 Fall AGU Meeting San Francisco, CA 14 December 2004 A. A.T. Fisher 1 and Tetsuro Urabe 2 and the IODP Expedition 301 Scientific Party 1 University of California, Santa Cruz 2 University of Tokyo A. A.T. Fisher 1 and Tetsuro Urabe 2 and the IODP Expedition 301 Scientific Party 1 University of California, Santa Cruz 2 University of Tokyo IODP Expedition 301: The Hydrogeologic Architecture of Basaltic Oceanic Crust: Compartmentalization, Anisotropy, Microbiology, and Crustal-scale Properties on the Eastern Flank of Juan de Fuca Ridge

2 Expedition 301 Science Party: A. Fisher, T. Urabe, A. Klaus, A. Bartetzko, K. Becker, R. Coggon, M. Dumont, B. Engelen, S. Goto, V. Heuer, S. Hulme, M. Hutnak, F. Inagaki, G. Iturrino, S. Kiyokawa, M. Lever, S. Nakagawa, M. Nielsen, T. Noguchi, W. Sager, M. Sakaguchi, B. Steinsbu, T. Tsuji, C. G. Wheat Additional proponents and collaborators: J. Alt, W. Bach, J. Baross, J. Cowen, S. D’Hondt, E. E. Davis, D. Kadko, M. McCarthy, J. S. McClain, M. J. Mottl, M. Sinha, G. Spinelli, V. Spiess, R. Stephen, D. Teagle, H. Villinger, L. Zühlsdorff

3 Fundamental questions addressed by IODP Expedition 301 and related experiments What are the magnitude and nature (distribution, extent of channeling) of permeability in crustal fluid-rock systems, variations, scaling (temporal, spatial)? What are the magnitudes and directions of driving forces, fluid fluxes, and associated solute and heat transport? What are the magnitude and nature of storage properties, variations with fluid pressure, scaling (temporal, spatial)? What are relations between fluid flow, vertical and horizontal compartmentalization, microbiological communities, seismic properties, alteration, structure, and primary crustal lithology? How large are distinct fluid reservoirs, what are fluid residence times and fluid velocities, and how do these respond to transient processes (tides, seismic events)? What are the magnitude and nature (distribution, extent of channeling) of permeability in crustal fluid-rock systems, variations, scaling (temporal, spatial)? What are the magnitudes and directions of driving forces, fluid fluxes, and associated solute and heat transport? What are the magnitude and nature of storage properties, variations with fluid pressure, scaling (temporal, spatial)? What are relations between fluid flow, vertical and horizontal compartmentalization, microbiological communities, seismic properties, alteration, structure, and primary crustal lithology? How large are distinct fluid reservoirs, what are fluid residence times and fluid velocities, and how do these respond to transient processes (tides, seismic events)?

4 Things we want to understand Things we measure Permeability links observation and process Permeability is at the center of many of these questions…

5 What is the diversity, distribution, and size of ecosystems? What is the diversity, distribution, and size of ecosystems? What happens when we move from oceanic sediments to basement? What happens when we move from oceanic sediments to basement? How does microbiology relate to other aspects of water/rock? How does microbiology relate to other aspects of water/rock? modified from Parkes et al. (1994), D’Hondt et al. (2003) …and so is the subseafloor biosphere!

6 The geology is typical in many ways. The geology is typical in many ways. Young crust, thick sediments, create extreme conditions we can measure and sample. Young crust, thick sediments, create extreme conditions we can measure and sample. Existing boreholes/CORKs help us understand the system, save time in creating a network of observatories. Existing boreholes/CORKs help us understand the system, save time in creating a network of observatories. Link with future cabled observatory system: NEPTUNE. Link with future cabled observatory system: NEPTUNE. Eventually, we will need to test several areas, but this is the best place to start. Why work on the eastern flank of Juan de Fuca Ridge?

7 First controlled, cross-hole seafloor experiment; First controlled, cross-hole seafloor experiment; First multi-directional hydrogeologic experiment (both vertical and multi-azimuth); First multi-directional hydrogeologic experiment (both vertical and multi-azimuth); First active large-scale assessment of storage properties and effective porosity; First active large-scale assessment of storage properties and effective porosity; First combined (simultaneous, co-located) hydrogeologic, microbiological, tracer, seismic experiment; First combined (simultaneous, co-located) hydrogeologic, microbiological, tracer, seismic experiment; First long-term active experiment (hours to multi-year); First long-term active experiment (hours to multi-year); First attempt to measure multiple scales (temporal, spatial) with the same techniques, link to primary lithology, alteration, etc. First attempt to measure multiple scales (temporal, spatial) with the same techniques, link to primary lithology, alteration, etc. Expedition 301 and follow-up expeditions will provide many new opportunities and results…

8 Create/modify a network of boreholes (two existing, two new), penetrating up to ~300-400 m of permeable basement; Conduct wireline logging, VSP, short-term packer tests; Install long-term observatories (CORKs) to monitor pressure, temperature, collect fluid samples, colonize microbes; and Collect sediment and rock samples and evaluate lithology, alteration, microbiology, fluid chemistry. Prepare for installation of additional holes to conduct cross- hole hydrogeologic, microbiological, geochemical, and seismic experiments at a range of spatial and temporal scales (meters to kilometers, minutes to years) in the same holes. Create/modify a network of boreholes (two existing, two new), penetrating up to ~300-400 m of permeable basement; Conduct wireline logging, VSP, short-term packer tests; Install long-term observatories (CORKs) to monitor pressure, temperature, collect fluid samples, colonize microbes; and Collect sediment and rock samples and evaluate lithology, alteration, microbiology, fluid chemistry. Prepare for installation of additional holes to conduct cross- hole hydrogeologic, microbiological, geochemical, and seismic experiments at a range of spatial and temporal scales (meters to kilometers, minutes to years) in the same holes. Summary of IODP 301 Operational Plans

9 Second Ridge (SR): Primary Sites First Ridge (FR), Deep Ridge (DR): Secondary Sites Second Ridge area IODP 301 site locations…

10 Planned SR operations Replace CORKs at 1026B (higher priority), 1027C (lower priority) Replace CORKs at 1026B (higher priority), 1027C (lower priority) Drill holes at Site 1301, ≤400 m into basement, core, log, BHTV, VSP, packer, CORK multiple intervals, additional sediment coring Drill holes at Site 1301, ≤400 m into basement, core, log, BHTV, VSP, packer, CORK multiple intervals, additional sediment coring Drill Hole SR-2A, ≤200 m into basement, core, sample, log, BHTV, VSP (offset), packer, CORK multiple intervals Drill Hole SR-2A, ≤200 m into basement, core, sample, log, BHTV, VSP (offset), packer, CORK multiple intervals Long-term testing (1-3 years) within and between holes Long-term testing (1-3 years) within and between holes

11 Simultaneous and Co-located Hydrogeologic, Microbiological, Seismic, Tracer Experiments (1) Hydrogeologic Experiments: Single-hole tests Single-hole tests Use CORK’ed wells as observation points, pump across wells Use CORK’ed wells as observation points, pump across wells Pump for 24 hours, let equilibrate for 6-12 months, open valve(s) to overpressured interval(s), allow to flow for 12-24 months = "artesian well" test Pump for 24 hours, let equilibrate for 6-12 months, open valve(s) to overpressured interval(s), allow to flow for 12-24 months = "artesian well" test Test multiple scales, directional properties, differences in properties and relations Test multiple scales, directional properties, differences in properties and relations

12 Simultaneous and Co-located Hydrogeologic, Microbiological, Seismic, Tracer Experiments (2) Microbiological Experiments: Which microbes live where, how? Which microbes live where, how? Three main stages of analysis: Three main stages of analysis: (a) Sediment coring, sampling (b) Basement coring, sampling (c) Long-term fluid sampling, incubation Long-term samplers and colonization substrate deployed within sealed boreholes Long-term samplers and colonization substrate deployed within sealed boreholes Vent overpressured system at seafloor, time-series sampling, additional seafloor experiments Vent overpressured system at seafloor, time-series sampling, additional seafloor experiments

13 Simultaneous and Co-located Hydrogeologic, Microbiological, Seismic, Tracer Experiments (3) Seismic Experiments: Collect wireline logs in deep basement holes Collect wireline logs in deep basement holes Single-hole VSP in Holes 1301B and SR-2A Single-hole VSP in Holes 1301B and SR-2A Offset VSP, shoot from another ship to the hole Offset VSP, shoot from another ship to the hole Determine directional basement seismic properties, relations to hydrogeologic and other properties Determine directional basement seismic properties, relations to hydrogeologic and other properties

14 Simultaneous and Co-located Hydrogeologic, Microbiological, Seismic, Tracer Experiments (4) Tracer Experiments: Thermal, modeling, and geochemical studies suggest fluid velocities on the order of kilometers per year Thermal, modeling, and geochemical studies suggest fluid velocities on the order of kilometers per year Pump multiple tracers in multiple holes and depths during hydrogeologic tests Pump multiple tracers in multiple holes and depths during hydrogeologic tests Monitor individual holes and depths for tracer return patterns (single-hole tests) Monitor individual holes and depths for tracer return patterns (single-hole tests) Monitor for across-hole tracer appearance, also monitor natural discharge on Baby Bare outcrop Monitor for across-hole tracer appearance, also monitor natural discharge on Baby Bare outcrop

15 Expedition 301 CORK system features In new holes: four nested casing strings (three to hold open hole, one for CORK) In new holes: four nested casing strings (three to hold open hole, one for CORK) Multiple sealing systems: cement, packer(s), CORK body, CORK casing (top and bottom) Multiple sealing systems: cement, packer(s), CORK body, CORK casing (top and bottom) Tubing extends to depth for fluid and microbio sampling, pressure monitoring, several kinds of umbilicals used Tubing extends to depth for fluid and microbio sampling, pressure monitoring, several kinds of umbilicals used Autonomous temperature loggers, OsmoSamplers, microbio cells within/below CORK, hung on Spectra cable Autonomous temperature loggers, OsmoSamplers, microbio cells within/below CORK, hung on Spectra cable Pressure logger attached to CORK head by ROV/sub after CORK deployment Pressure logger attached to CORK head by ROV/sub after CORK deployment System allows monitoring of formation and cased intervals, to evaluate CORK performance System allows monitoring of formation and cased intervals, to evaluate CORK performance

16 Expedition 301 CORKs, casing hangers

17 Hoisting CORK onto rig floor Sampling/monitoringbay Top seal

18 Attaching CORK running tool

19 Raising CORK in the rig in preparation for deployment through the moon pool

20 Running tubing, protective centralizers

21 Attaching umbilicals to pass-throughs on main CORK seal Hero Hero Hero Hero

22 Autonomous temperature loggers, attached to downhole instrumentation and cables

23 Preparing OsmoSamplers and microbiological substrate cells

24 Downhole microbiological instrumentation

25 Three bays on CORK head for uphole instrumentation and access to samples

26 Three CORKs deployed during IODP Expedition 301

27 IODP 301 collected and tested many basement and sediment samples

28 Extensive microbiological sampling and analysis (9% of basement rock, much of the sediment)

29 Summary of IODP 301 basement results

30 Post-IODP 301 operations E. Davis (PGC) and R. Dixon (US-IO) returned to Exp. 301 CORKs on R/V Thomas G. Thompson in September 2004 E. Davis (PGC) and R. Dixon (US-IO) returned to Exp. 301 CORKs on R/V Thomas G. Thompson in September 2004 Installed pressure loggers, closed valves Installed pressure loggers, closed valves Recovered some OsmoSamplers from CORK heads Recovered some OsmoSamplers from CORK heads Inspected CORK installations Inspected CORK installations

31 ROPOS operations: September 2004

32 Expedition 301 achieved critical objectives Successes are remarkable considering limited time available to prepare… Successes are remarkable considering limited time available to prepare… Now poised to finish drilling and related work, conduct long-term, active tests in the crust… Now poised to finish drilling and related work, conduct long-term, active tests in the crust… Appropriate for the first expedition of IODP - a new kind of experiment Appropriate for the first expedition of IODP - a new kind of experiment

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