Overview of USGS Carbon Sequestration Geologic Research and … · 2019-03-04 · Overview of USGS...
Transcript of Overview of USGS Carbon Sequestration Geologic Research and … · 2019-03-04 · Overview of USGS...
Overview of USGS Carbon Sequestration – Geologic Research
and Assessments Project
December, 2016
U.S. Geological Survey
Department of the Interior
Peter D. Warwick and the Geologic CO2 Sequestration Project Team
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Outline for Presentation
• U.S. Geological Survey (USGS) carbon sequestration Congressional mandate
• Why is geologic CO2 sequestration important?
• What is the USGS geologic carbon sequestration project doing to address CO2 storage?
• Summary of take-away points
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Carbon Sequestration Mandate
• The USGS Carbon Sequestration Program is funded by the USGS Climate and Land Use Change (CLU) Mission Area.
• The Carbon Sequestration Program is responsive to The Energy
Independence and Security Act (EISA) of 2007 (P.L. 110-140) which calls for the USGS to develop a methodology for, and then complete a national assessment of, the geologic storage capacity for CO2, and to evaluate associated geologic risks.
• EISA also directed the USGS to conduct a national assessment to quantify
the amount of carbon stored in ecosystems, the capacity of ecosystems to sequester carbon and the rate of greenhouse gas flux in and out of ecosystems (biologic carbon sequestration).
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Why is geologic CO2 sequestration important?
Geologic storage of CO2 is essential to meet future CO2 emission reduction scenarios
• By 2050, carbon capture and geologic storage (CCS) should contribute about 14% of total emission reductions through 2050 in the 2° C Scenario (International Energy Agency, 2012, 2013)
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Carbon capture and storage (CCS) contributes 14% of total emission reductions through 2050 in 2° C Scenario compared to 6° C Scenario
IEA (2013) Technology Roadmap Energy Technology Perspectives Carbon capture and storage IEA (2012) Energy Technology Perspectives 2012
60
50
40
30
0
20
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Emis
sio
ns
(GtC
O2)
2009 2020 2040 2030 2050
Carbon capture & geologic storage 14% (~7-10 Gt CO2/yr)
Power generation efficiency & fuel switching 3%
Renewables 21%
Nuclear 8%
End use fuel switching 12%
End-use fuel and electricity efficiency 42%
2° C, 450 ppm
6° C
Year
1.5° C ?
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USGS National Assessment of
Geologic Carbon Dioxide Storage
Resources mean = 3,000 Gt CO2 storage
U.S. Geological Survey Geologic Carbon Dioxide Storage Resources Assessment Team (2013)
The regions with the largest technically accessible storage resources (circled) are the Coastal Plains (mostly in the U.S. Gulf Coast), Rocky Mountains and Northern Great Plains, and Alaska (mostly North Slope)
Gt = metric gigaton
USGS estimates of technically accessible storage resources for CO2 in the United States by region
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Source: Litynski (2015)
(Industrial Carbon Capture and Storage)
IGCC = Integrated gasification combined cycle EOR = enhanced oil recovery MTPY = million tons per year; DOE = U.S. Department of Energy
Examples of major U.S. CCS projects
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Source: Litynski (2015)
Example of a large U.S. CCS project
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The following slides illustrate major focus areas for the USGS Carbon Sequestration – Geologic Research and Assessments Project
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What happens when you pump carbon dioxide underground?
Major questions addressed by USGS research: How much CO2 can be stored underground nationwide?
How much oil can be produced by injecting CO2 into reservoirs for enhanced oil recovery?
What are the environmental risks of storing CO2 in underground reservoirs? What is the potential for CO2 leakage, impacts to drinking water, and induced seismicity?
CO2 injection well in Mississippi
The USGS is monitoring induced seismicity at the Arthur Daniels Midland industrial carbon dioxide injection project in Decatur, IL.
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Methodology Development and Assessment of National CO2 Enhanced Oil Recovery and Associated CO2 Storage Potential
Source: Global CCS Institute (2015)
The USGS has developed an assessment methodology for estimating the potential incremental technically recoverable oil resources resulting from CO2-enhanced oil recovery (CO2-EOR) in reservoirs with appropriate depth, pressure, and oil composition. The methodology also includes a procedure for estimating the CO2 that remains in the reservoir after the CO2-EOR process is complete (Warwick and others, in press)
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• CO2 density and geothermal gradient research
• Underpressure in the basins of the Great Plains
Geological studies of reservoirs and seals in selected basins with high potential for CO2
storage
Nelson and others (2015)
Michigan Basin (Buursink, 2014) 12
• Geochemist’s Workbench software package for modeling geochemical systems
• TOUGH2-ECO2N reservoir geochemical-reaction modeling software
• This study aims to combine the modeling capabilities of these two software programs by using the newly developed re-entrant self-linking software object, ChemPlugin
• Collaborative research effort that includes the USGS, University of South Florida, Illinois State Geological Survey, and Aqueous Solutions, LLC (developers of The Geochemist’s Workbench and ChemPlugin).
Modeling Supercritical CO2 Migration and Geochemical Reactions in Saline Reservoirs
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Natural CO2 reservoirs as analogues for CO2 storage
• Use natural CO2 reservoirs to investigate potential leakage risk and rates along faults and through breached seals
• Evaluate availability of natural CO2 resources that will
compete with anthropogenic CO2 for use in enhanced oil recovery – Study natural gas isotope geochemistry (including noble gases)
– Build geochemical database and characterize the size, timing and migration of natural accumulations within total CO2 systems
– Work with USGS Produced Waters Project by evaluating reservoir microbiology and water geochemistry
– Establish multiple confidentiality and assistance agreements with natural gas producers
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• Helium Assessment is the result of Section 16 of the Helium Sterwardship Act of 2013, which directs the USGS to “complete a national helium gas assessment that identifies and quantifies the quantity of helium”
• This assessment leverages ongoing Geologic CO2 Sequestration Project Tasks, primarily Natural CO2 research, and the CO2-Enhanced Oil Recovery Assessment
Helium inventory
Ballentine and others (2002); Holland and Gilfillan (2013)
• Worked with Bureau of Land Management (BLM) to obtain significant volumes of internal helium data
• Created a public database of helium concentrations in United States Wells (Brennan and others, 2016)
• National helium assessment underway
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Illinois Basin
USGS Mt. Simon Storage Assessment Unit
Well data
Mount Simon thickness
Develop economic models:
• Representative economic/engineering cost models for saline formations
• Economic cost model for carbon dioxide extraction from natural sources
Describe/delineate costs of
• Site preparation and investment
• Pressure management
• Risk mitigation
• Monitoring
Work in coordination with the USGS Economics, Energy Resources, and Future Energy Supply project
Economics of CO2 Storage and Enhanced Oil Recovery (EOR)
Petroleum engineering modeling tools that estimate injection capacities and pressure buildup for Mount Simon Sandstone
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Storage of CO2 in unconventional geologic reservoirs
Tollefson (2013)
CO2 storage in basaltic and ultra-mafic rocks
Goodman and others (2014) 17
The USGS also studies rock types that have the potential to store CO2 through different mechanisms, including CO2 mineralization in mafic basalts and ultramafic rocks, and CO2 sorption onto organic-rich shales and coals.
Background on Decatur & CCS
Strandli and others, 2014
Lower perm. zones
• Injection occurs right over crystalline basement into the lower Mount Simon Sandstone
• Extensive evidence of heterogeneous permeability structure (vertically, horizontally)
• Similar physics as wastewater injection sites except: buoyancy, compressibility, and mobility of super critical CO2
• Same concerns: pore pressure change, mass added, poro-elastic strain changes
• Better opportunity to learn about physical mechanisms governing induced seismicity:
– Seismic monitoring
– In-situ stress analyses
– Thermal, hydraulic, and mechanical models of injection & deformation
Induced seismicity associated with CO2 geologic storage
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Locations of microseismic events and USGS monitoring stations
Induced seismicity associated with CO2 geologic storage
39.90 N
88.92 W 88.88 W
Borehole station
Surface station
Kaven and others (2015)
Double-difference relocated microseismicity using differential travel times from phase arrival times and waveform cross correlation (correlation coefficient ≥ 0:7). Focal mechanisms are from P-wave polarity for six events. Regional orientation of the maximum horizontal principal stress (SHmax) is indicated by opposing arrows.
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“First, in order to better understand and manage carbon emissions on public lands, the Interior Department’s U.S. Geological Survey will establish and maintain a public database to account for the annual carbon emissions from fossil fuels developed on federal lands.” U.S. Department of the Interior (2016)
Estimating greenhouse gas emissions from
fossil fuels produced from Federal lands
USGS Federal Lands Greenhouse Gas Emissions and Sequestration Project (FLGGES)
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• Report both emissions and sinks (and both gross and net emissions)
• Emissions: • CO2 + CH4 + N2O
• resulting from the production and end use of onshore and offshore coal, oil, and natural gas produced on federal lands
• Sinks: • Biological carbon sequestration • (Later) Re-injection and enhanced oil recovery geologic
sequestration
• Annually from 2005 to present
• For all Federal lands and Federal lands by state
FLGGES Desired End Product
Merrill and others (2016) 21
Department of Interior • Office of Natural Resources Revenue (ONRR) • Bureau of Land Management (BLM) • Bureau of Ocean Energy Management (BOEM) Additional Agencies • Environmental Protection Agency (EPA) • U.S. Department of Agriculture (USDA) • Mine Safety and Health Administration (MSHA)
Modified EPA GHG Inventory
Methodology
Fossil Fuel Production from
Federal Lands ONRR
Biological Sequestration
USGS + USDA
NET EMISSIONS
Emissions from Activities
BLM, BOEM, MSHA
Basic FLGGES Method
GHG Emissions: Fossil Fuels from Federal Lands
Geologic Sequestration
(future versions?)
Emissions Sequestration
Forested Land (USDA)
Non-forested Land (USGS)
Inputs
Method
Outputs
Abbreviations: Greenhouse Gas (GHG)
Reconciliation of Land
Representation
Merrill and others (2016) Reed (2016) 22
Cooperators and outreach
• State Geological Survey and university Co-ops
• Stanford and Univ. Texas at Austin CO2 working groups
• Member of DOE National Risk Assessment Partnership Stakeholders Group
• Member of Interagency Carbon Capture and Storage working group
• Member of International Standards Organization working groups on Carbon Capture and Storage and CO2-enhanced oil recovery
• Member of International Energy Agency working group on assessing CO2 storage capacities
• Industry partners (Electric utilities, software developers, oil and gas operators)
CO2 project website: http://go.usa.gov/8X8
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Next steps • Complete national CO2-enhanced oil recovery assessment • Expand induced seismicity research • Better characterize potential geologic CO2 storage
formations • Build in pressure, injection rate, time, and economics into
future CO2 storage assessments • Conduct numerical modeling for hydrodynamic and
geochemical interactions with CO2 storage • Complete national helium inventory • Complete Federal lands greenhouse gas emissions and
sequestration
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Summary of take-away points • Geologic storage of CO2 is essential to meet future CO2
emission reduction scenarios1
The USGS is a recognized world leader in:
• The geology of CO2 storage
• Resource assessments CO2 storage
Enhanced oil recovery
Economics of CO2 storage and energy-related resources
• Induced seismicity
1Intergovernmental Panel on Climate Change (2014); International Energy Agency (2015)
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References Cited Ballentine C.J., Burnard P.G., 2002, Production, release and transport of noble gases in the continental crust. In: Porcelli DR, BallentineCJ, Weiler R (eds) Noble gases in geochemistry and cosmochemistry, p. 481–538.
Berennan, S.T., East, J.A., Dennen, K.O., Jahediesfanjani, Hossein, Varela, Brian, 2016, Helium concentrations in United States wells: U.S. Geological Survey
Provisional Database, http://energy.usgs.gov/EnvironmentalAspects/EnvironmentalAspectsofEnergyProductionandUse/GeologicCO2Sequestration.aspx#377624-data.
Buursink, M.L., 2014, Significance of carbon dioxide density estimates for basin-scale storage resource assessment: Energy Procedia, v. 63, p. 5130–5140, http://dx.doi.org/10.1016/j.egypro.2014.11.543
Department of Energy National Energy Technology Laboratory, 2010, Carbon dioxide enhanced oil recovery, untapped domestic energy supply
and long term carbon storage solution: Department of Energy National Energy Technology Laboratory, 30 p., https://www.netl.doe.gov/file%20library/research/oil-gas/small_CO2_EOR_Primer.pdf.
Hamburger, M.W., Shoemaker, K., Horton, S., DeShon, H., Withers, M., Pavlis, G.L., and Sherrill, E., 2011, Aftershocks of the 2008 Mt.
Carmel, Illinois, earthquake: Evidence for conjugate faulting near the termination of the Wabash Valley fault system, Seismol. Res. Lett. 82, 735–747, doi: 10.1785/Gssrl.82.5.735.
Global CCS Institute, 2015, website, www.globalccsinstitute.com/content/information-resource.
Holand, Greg, and Gilfillan, Stuart, 2013, Application of noble gases to the viability of CO2 storage, in Burnard, Pete, ed., The noble gases as geochemical tracers, advances in isotope geochemistry, Springer-Verlag Berlin Heidelberg, p. 177-223, http://dx.doi.org/10.1007/978-3-642-28836-4_8.
Intergovernmental Panel on Climate Change, 2014a, Summary for policymakers, in Edenhofer, O., Pichs-Madruga, R., Sokona, Y., Farahani, E., Kadner, S., Seyboth, K., Adler, A., Baum, I., Brunner, S., Eickemeier, P., Kriemann, B., Savolainen, J., Schlömer, S., von Stechow, C., Zwickel T., and Minx, J.C., eds., Climate Change 2014—Mitigation of Climate Change—Contribution of Working Group III to the fifth assessment report of the Intergovernmental Panel on Climate Change: Cambridge, United Kingdom, and New York, New York, Cambridge University Press, 31 p.
International Energy Agency, 2012, Pathways to a clean energy system, Energy technology perspectives 2012: International Energy Agency, Paris, France, 686 p., https://www.iea.org/publications/freepublications/publication/ETP2012_free.pdf.
International Energy Agency, 2013, Carbon capture and storage, technology roadmap: International Energy Agency, Paris, France, 59 p., http://www.iea.org/publications/freepublications/publication/technology-roadmap-carbon-capture-and-storage-2013.html.
International Energy Agency, 2015, World energy outlook special report, energy climate and change: International Energy Agency, Paris, France, 196 p. https://www.iea.org/publications/freepublications/publication/weo-2015-special-report-energy-climate-change.html.
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References Cited (cont.) Kaven, J.O., Hickman, S.H., McGarr, A.F., and Ellsworth, W.L., 2015, Surface monitoring of microseismicity at the Decatur, Illinois, CO2 sequestration demonstration site: Seismological Research Letters, vol. 86, no. 4, p. 1096–1101., http://dx.doi.org/10.1785/0220150062.
Le Quéré and 49 other authors, 2014, Global carbon budget 2013: Earth System Science Data, v. 6, p. 335-263., http://dx.doi.org/10.5194/essd-6-235-2014.
Litynski, J.T., 2015, U.S. DOE Carbon Capture Program: Air and Waste Management Association – Florida Section 51st Annual Conference, October 28th, 2015, 26 p., http://floridasection.awma.org/Conference_Files/2015_Conference_Presentations/CCS_US_Litynski_AWMA2_27Oct2015.pdf.
Merrill, Matthew, Freeman, Philip, Warwick, Peter, 2016, Status Report–Estimating greenhouse gas emissions from fossil fuels produced from Federal lands: U.S. Geological Survey Stakeholder Briefing for Federal Lands Greenhouse Gas Emissions and Sequestration (FLGGES), December 2, 2016, Reston, VA, 32 p. http://energy.usgs.gov/Portals/0/Rooms/co2_sequestration/text/FLGGES%20public%20meeting%20Emissions_WebFinal.pdf.
Nelson, P.H., Gianoutsos, N.J., and Drake R.M. II, 2015, Underpressure in Mesozoic and Paleozoic rock units in the midcontinent of the United States: American Association of Petroleum Geologists Bulletin, v. 99, no. 10, p. 1861 – 1892, http://dx.doi.org/10.1306/04171514169.
Reed, Bradley, 2016, Approach for estimating biological carbon sequestration on Federal lands: U.S. Geological Survey Stakeholder Briefing for Federal Lands Greenhouse Gas Emissions and Sequestration (FLGGES), December 2, 2016, Reston, VA, 24 p.
Strandli, C.W., Mehnert, Edward, Benson, S.M., 2014, CO2 plume tracking and history matching using multilevel pressure monitoring at the Illinois Basin – Decatur Project , Energy Procedia, v. 63, p. 4473–44484, http://dx.doi.org/10.1016/j.egypro.2014.11.483.
Warwick, P.D., Verma, M.K., Attanasi, E.D., Olea, R.A., Blondes, M.S., Freeman, P.A., Brennan, S.T. Merrill, M.D., Jahediesfanjani, Hossein, Roueche, J.N., and Lohr, C.D., 2016 in press, A database and probabilistic assessment methodology for carbon dioxide enhanced oil recovery and associated carbon dioxide retention in the United States: Energy Procedia, The Greenhouse Gas Control Technologies (GHGT) conference, 14-18 November, 2016, Lausanne, Switzerland, 5 p.
U.S. Energy Information Administration, 2015, Annual energy outlook 2015 with projections to 2040: U.S. Energy Information Administration [Report] DOE/EIA-0383(2015), ES1 – G1 p., accessed June 4, 2014, at http://www.eia.gov/forecasts/aeo/pdf/0383(2014).pdf.
U.S. Department of the Interior, 2016, Modernizing the Federal coal program: U.S. Department of the Interior Fact Sheet, 3 p., https://www.blm.gov/style/medialib/blm/wo/Communications_Directorate/public_affairs/news_release_attachments.Par.47489.File.dat/Coal%20Reform%20Fact%20Sheet%20Final.pdf.
U.S. Environmental Protection Agency, 2015, Inventory of U.S. Greenhouse Gas Emissions and Sinks – 1990-2013: U.S. Environmental Protection Agency EPA 430-R-15-004, p. ES1-10-71., http://www3.epa.gov/climatechange/ghgemissions/usinventoryreport.html.
U.S. Geological Survey Geologic Carbon Dioxide Storage Resources Assessment Team, 2013, National assessment of geologic carbon dioxide storage resources—Results: U.S. Geological Survey Circular 1386, 41 p., available online at http://pubs.usgs.gov/circ/1386/.
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Carbon Sequestration—Geologic Research and Assessments Project
For more information contact: Peter D. Warwick [email protected] 703-648-6469
Project Website
Selected Publications
http://go.usa.gov/8X8
http://go.usa.gov/xZDpz 28