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Carbon Capture and Geologic Storage

Carbon Capture and Geologic Storage. Larry R. Myer Earth Sciences Division Lawrence Berkeley National Laboratory Physics of Sustainable Energy March 1-2, 2008. Topics. Introduction Capture options CCS costs Storage options/mechanisms Storage capacity Geologic storage risks

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Carbon Capture and Geologic Storage

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  1. Carbon Capture and Geologic Storage Larry R. Myer Earth Sciences Division Lawrence Berkeley National Laboratory Physics of Sustainable Energy March 1-2, 2008 LM-01L

  2. Topics • Introduction • Capture options • CCS costs • Storage options/mechanisms • Storage capacity • Geologic storage risks • Need for monitoring • Field studies • Beyond coal LM-01L

  3. CO2 Capture and Storage Technology • CCS is a four-step process • Pure stream of CO2 captured from flue gas or other process stream • Compressed to ~100 bars • Transported to injection site • Injected deep underground into geological formation and stored safely for thousands of years Capture Compression Underground Injection Pipeline Transport LM-01L

  4. Options for CO2 Capture • Post-combustion • Established technology • Pre-combustion • Established technology for other applications • Not demonstrated for power production • Oxygen combustion • Not demonstrated for power production Source: S Benson, Stanford LM-01L

  5. CCS Costs • Power generation from coal • Additional $35 - 45/ MWh • $50 – 60/tonne CO2 avoided • Power generation from natural gas • Additional $30/MWh • $80/tonne CO2 avoided • Industrial processes producing pure CO2 stream • $20 – 30/tonne CO2 avoided • EOR credit can offset ~$20/tonne Source: H Herzog, MIT LM-01L

  6. Elements of Cost Estimates • Region specific (CA conditions for given costs) • 90% of CO2 is captured • Transport and storage included ($10/tonne) • Monitoring costs estimated as $.10 - .50/tonne • Current technology • Operations at scale LM-01L

  7. Primary Storage Options • Oil and gas reservoirs • Storage with Enhanced Oil Recovery (EOR), Enhanced Gas Recovery (EGR) • Storage only • Deep, unminable coal beds • Storage with Enhanced Coal Bed Methane (ECBM) recovery • Saline formations • Storage only LM-01L

  8. Geologic Storage Mechanisms • Physical/structural trapping • Dissolution • Phase trapping • Mineralization • Surface adsorption W Gunter, ARC S Benson, Stanford, LM-01L

  9. CO2 EOR is a Commercial Technology Need to optimize EOR for CO2 storage Explore less favorable EOR targets LM-01L

  10. Saline Formation Storage Is Already Under Way • Statoil injects 1x106 tons per year at Sleipner • BP to inject 0.8x106 tons per year at In Salah LM-01L

  11. Prospective Saline Formation Storage Broadly Distributed From Bradshaw and Dance 2005 “It is likely that the technical potential for geological storage is sufficient to cover the high end of the economic potential range(2200 GtCO2), but for specific regions, this may not be true.” IPCC, 2005 LM-01L

  12. Regional Studies Provide Capacity Estimates and Source-Sink Matches Gas reservoir capacity: 1.7Gt Oil reservoir capacity: 3.6Gt LM-01L

  13. HSE Risks of Geologic Storage • Impacts of unintended leakage • Health and safety of workers and general population • Environmental impacts • Unwanted intrusion into drinking water • Earthquakes • Unwanted intrusion of saline fluids Tree kill at Mammoth Mountain, CAhttp://quake.wr.usgs.gov/prepare/factsheets/CO2/ LM-01L

  14. International Consensus on Geologic Storage Issues Provided by IPCC Report “ With appropriate site selection informed by available subsurface information, a monitoring program to detect problems, a regulatory system, and the appropriate use of remediation methods to stop or control CO2 releases if they arise, the local health, safety, and environment risks of geological storage would be comparable to risks of current activities such as natural gas storage, EOR, and deep underground disposal of acid gas.” IPCC, 2005 LM-01L

  15. Risk Decreases Rapidly After Operational Phase Pressure recovery Secondary trapping mechanisms Confidence in predictive models Risk Profile Injection begins Injection stops 2 x injection period 3 x injection period n x injection period Monitor Calibrate & Validate Models Calibrate & Validate Models Model Source: S Benson, Stanford LM-01L

  16. Plume Mobility Decreases with Time Reservoir simulation of CO2 plume (C Doughty, LBNL) LM-01L

  17. Pressure Decays Rapidly in Large Reservoirs Reservoir simulation of pressure change (C Doughty, LBNL) LM-01L

  18. Why Monitor? • Confirm storage efficiency and processes • Ensure effective injection controls • Detect plume location and leakage from storage formation • Ensure worker and public safety • Design and evaluate remediation efforts • Detect and quantify surface leakage • Provide assurance and accounting for monetary transactions • Settle legal disputes LM-01L

  19. Well CO2 A Substantial Portfolio of Monitoring Techniques are Available • Seismic and electrical geophysics • Well logging • Hydrologic pressure and tracer measurements • Geochemical sampling • Remote sensing • CO2 sensors • Surface measurements Surface seismic VSP (Figures courtesy of S Benson) Cross-well LM-01L

  20. 30 0 Offset (m) ‘B’ Sand G.L. Depth (ft) Top of ‘C’ Sand Injection Well Monitoring Well CO2 Plume Monitoring of CO2 Using Seismic Methods Time-lapse seismic monitoring results from Sleipner, after Chadwick et al., 2005 Cross-well imaging and RST logs from Friosaline injection test(Daley et al 2006) LM-01L

  21. Pilots Provide Regional Knowledge Base Essential for Large Scale Implementation • Pilots demonstrate best sequestration options, unique technologies and approaches, in region • Pilots involve site-specific focus for • Testing technologies • Defining costs • Assessing leakage risks • Gauging public acceptance • Exercising regulatory requirements • Validating monitoring methods Photos from Frio saline formation CO2 injection test LM-01L

  22. CCS Beyond Coal • Natural gas • Industrial processes • Cement • Refineries (hydrogen plants) • Ammonia • Fermentation processes (eg. biofuels) • Linking with terrestrial (forest management) LM-01L

  23. Current Status • IPCC Special Report on CCS; CCS included in IPCC 4th Assessment as mitigation option • Small number of commercial projects underway world-wide • US DOE research effort focused on field testing (~$125M/yr and increasing) • Numerous legislative actions at state and federal level LM-01L

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  25. Summary • The technology necessary to undertake CCS is available today • Cost-effectiveness is driven mostly by capture costs • Risks can be managed • Field testing is essential to gain experience • Plenty of opportunities for innovation • Fossil power generation optimized for CCS • Basic physics of storage mechanisms • New monitoring approaches, increased resolution • Thinking beyond coal LM-01L

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