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Explore the unique possibilities of studying coupled processes in the subsurface at DUSEL. Discover the benefits of going underground and the major areas of research in hydrogeology, hydrologic and geologic processes, thermal/hydrologic coupling, and more.
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Coupled Processes at DUSEL: Unique Possibilities Brian McPherson and Eric Sonnenthal
Major Coupled Processes to Address at DUSEL • hydrogeology and the water cycle • coupled hydrologic and geologic processes in general • coupled hydrologic and chemical processes in general • coupled thermal/hydrologic processes and • geomicrobiologic activity • coupled fluid flow and heat flow • coupled fluid flow (pressure) and rock deformation (strain) • coupled fluid flow and chemically reactive transport • coupled fluid flow and mineralization (mineral/ore • formation) processes
Black Hills Salt Creek Anticline 2000 Oil or Gas Well Elevation (m) SL -2000 Data collected at bottom of borehole. Vertical Exaggeration x 16 -4000 Powder River Basin, Wyoming Question: What’s the major benefit to Earth Science of “going underground”? One Typical Approach to Subsurface Investigations: Use drill-hole data with computer model simulations
Proposed New Approach: Develop a US laboratory and observatory underground, inside the earth. Much like surgery permits a physician to examine internal bones and organs recognized on X-rays or CAT scans, NUSL will be a fully instrumented, dedicated laboratory and observatory for scientists and engineers to examine Earth’s interior. Courtesy: URL at Atomic Energy of Canada Ltd
Surface laboratories for core, water, gas, and microbial analyses, experiments, and archives
Deep Coupled Processes Laboratory: study coupling among thermal, mechanical, hydrological, chemical, and biological processes in the subsurface (injection and transport experiments at several different depths along highly instrumented and well-characterized fracture/matrix zones)
Some Example Coupled Process Studies • groundwater and geologic processes in general • spatial and temporal variation of recharge and its interaction with subsurface flow of groundwater • permeability and scales of evaluation • stress-state and permeability (critical stress)
Exploration and sustainability of groundwater is critical for an ever-increasing population: Groundwater is a key component of our water supply! Courtesy: Colorado Division of Water Resources, Office of the State Engineer
Fluid Flow and Transport Rationale: fluid flow influences resource recovery, water supply, contaminant transport and remediation • Characterization of active flow system • Characterization of fracture network • Verification of well and tracer test models • Recharge to deep groundwater system • Colloidal and bacterial transport • Paleohydrology
Question: What factors control how much water at the surface actually reaches the water table? However, what actually happens in the subsurface? • surface topography • surface geology • vegetation • climate • All of these aspects may be measured directly Photo Courtesy: Eric Small, Hydrology Program, New Mexico Tech
Photo Courtesy: Eric Small, Hydrology Program, New Mexico Tech Recharge and Infiltration Processes What if we could instrument the surface to provide “controlled” conditions of infiltration? And then also instrument the subsurface (e.g., of a very shallow drift or set up inter-drift instrumentation) to capture exactly what happens and observe what factors control how much water reaches depth? Photo Courtesy: URL at Atomic Energy of Canada Ltd.
Hypothesis: Linking Stress State to Permeability to Crustal Strength. • Permeable faults/fractures are critically-stressed • High permeability maintains hydrostatic pore pressure • Hydrostatic pore pressure results in high crustal strength
Coupled THMCB Processes in Fractured Rock Thermal Hydrologic Mechanical Chemical and Biological feedback to mass and energy transport • Level of characterization required to successfully model (or scale-up) transport (new geophysical imaging and tracer monitoring technologies) • Effect of physical and chemical heterogeneity on transport • Environmental processes affecting transport (e.g. induced thermal or stress changes, mineral dissolution or deposition, gas formation or consumption)
SCALE-OF-EVALUATION Permeability and other properties of crustal rocks may have different values depending on the scale at which it is evaluated. General quantitative or semi-quantitative relationships between rock properties and scale are dubious or do not exist.
How do we upscale point (space,time) measurements in a complex geologic system to larger regional processes? Whole earth - 107 m Regional scale 106 m Whole mine experiments - 104 m Stope, cavity scale - 102 m Tunnel, shaft scale - 101 Borehole, “laboratory” scale - 10-1 m Grain, sub-lab scale - 10-3 m
kPB =10-12 m2, kNB =10-15 m2 200 kPB =10-12 m2, kNB =10-16 m2 180 ) 2 kPB =10-12 m2, kNB =5 x 10-17 m2 - 160 m W 140 m ( 120 w o 100 l F t 80 a e H 60 40 20 0 Salt Creek Anticline Black Hills 2000 0 Elevation (m) -2000 Vertical Exaggeration x 9.9 (a) -4000 Regional-Scale Permeability of Powder River Basin, Including the Western Black Hills Area Modeled Heat Flow (c) 70 60 Observed Heat Flow ) 2 - m 50 W m ( 40 w o l F t a 30 e H 20 10 (b) 0 0 20 40 60 80 100 120 140 160 180 NE SW Distance (km) A A’ Black Hills From McPherson et al., 2001
Basin-scale -11 10 -13 10 Permeability (m2) Well-scale -15 10 Pierre Shale Powder River Basin Sandstones -17 10 Uinta Basin Strata Laboratory-scale -19 10 10 cm 10 m 10 km Scale of Measurement Expanded Capability Offered by DUSEL: Scaling Assess permeability variation at different spatial scales, using direct methods from within the rocks, and verify proxy methods typically used to evaluate permeability.
Some Other Hydrogeologic Issues • Groundwater Storage and Aquifer Sustainability: How sustainable is a given aquifer and why? • Paleohydrology: better understanding of paleohydrology and evolving water resource systems? • Deep Fractures: Can deep fracture systems be mapped, their origin determined, and can fracture flow processes be better characterized from in situ? • Flow in Deep Fractures: Are fractures at great depths closed or do they remain open to maintain deep circulation? • Contaminant Cleanup: by setting up mock contamination sites within DUSEL, using benign tracers, we can make direct studies of factors that control contaminant transport in the subsurface. • Well Testing Verification: Verification of well testing may be performed within DUSEL by direct measurements and observations within the subsurface. • Proxy Methods in General: DUSEL offers an unprecedented opportunity to verify proxy or remote methods. For example, the following are used to provide remote "images" of the subsurface: • seismic testing at the surface • satellite-based remote sensing (e.g., presence of water in the subsurface) • gravity methods at surface • electromagnetic methods at the surface • many others DUSEL offers an opportunity to verify these remote methods by direct observation and measurement.
Coupled Thermal-Hydrologic-Mechanical-Chemical-Biological Experiment Opportunities • Imperatives • Strong scale dependence • THMCB processes incompletely understood • The role of serendipity in scientific advance • Approach • Run-of-Mine Experiments (HCB) • Experiments Concurrent with Excavation of the Detector Caverns (THM) • Purpose-Built Experiments (THMCB) • Large Block Tests • Mine-By and Drift Structure Tests • Geophysical Monitoring • Educational Opportunities
New Opportunities for Analysis of Coupled THMCB Processes: Bringing together geochemists, petrologists, hydrologists, geophysicists, engineers, biologists Yucca Mountain Drift Scale Heater Test Examples • CO2 evolution and transport • Mineral precipitation/dissolution • Stable isotope fractionation • Permeability evolution • Rates of coupled processes • In-situ monitoring and sensors • Testing of new generation • reaction-transport models
Priority Attributes of DUSEL for Earth Science and Engineering Long-term access to large (~20+ km3) volume of subsurface in which geological features are well characterized in three dimensions, including appropriately placed sensing equipment. Ability to access this environment through selective/ choice placement of drill holes, underground workings, laboratories, or observatories. Accessed host rock should reach temperatures of 120°C and waterfilled fracture systems. Ability to modify geochemical characteristics of this environment by introduction of materials into holes or workings. At least one fracture zone should be accessed by multiple holes that are instrumented with an array of samplers for transport studies. If an existing mine is chosen as the DUSEL site, complete access to entire archive of existing data and samples.
EARTH SCIENCE AND ENGINEERING CRITERIA FOR DUSEL SITE Diverse chemical and physical environments, including: • Variety of hydrologic environments, such as highly permeable, near-surface soils and alluvium vs. deeper, low-permeability crystalline rocks. • Variety in groundwater compositions, such as high vs. low salinity, pH, and dissolved gas concentrations. • Variety of structural environments, especially density and orientation of faults and fractures. • Variety of geochemical environments, especially in concentration of reduced minerals (e.g., sulfides) vs. oxidized minerals (e.g., hematite).
WHAT ARE POSSIBLE BENEFITS TO SOCIETY? • RECOVERY OF NATURAL RESOURCES • Water Resources** • Energy Resources • Mineral Resources • Efficient Drilling and Excavation • BENEFICIAL USES OF UNDERGROUND SPACE • Waste Isolation • Energy Storage • Transportation Structures • ENVIRONMENTAL REMEDIATION • Waste Water • Remediation of Contaminated Groundwater
WHAT ARE POSSIBLE BENEFITS TO SOCIETY? • UNDERGROUND HAZARDS AND SAFETY • Earthquake Mechanics • Mine Safety and Health • Rock Reinforcement and Support • BIOLOGY AND ENVIRONMENTAL SAFETY • Global Warming • Groundwater Cleanup • Origins of Life • Disease Control