Geologic Carbon Dioxide and Energy-related Storage, Gas Resources, and Utilization Active
Caballos Novaculite Reservoir Outcrop
A major reservoir for naturally occurring carbon dioxide in southwestern Texas
Atop the LaBarge Platform
A major reservoir for naturally occurring carbon dioxide, helium, and hydrocarbon gases
Mud Volcanoes
Mud volcanoes at the Davis-Schrimpf Seep Field, Calipatria, California
Above-ground Infrastructure for Storing Excess Energy
Subsurface natural gas storage in the Hutchinson Salt Member in Reno County, Kansas
The objectives of this task are to conduct relevant research needed to 1) evaluate helium (He) and CO2 resources; 2) support future assessments of low-thermal gases and better understand their resources and potential for use as analogues for anthropogenic CO2 storage; 3) study the feasibility of large-scale CO2 mineralization in the United States; 4) develop pressure-limited dynamic models for regional CO2 storage assessments and economic evaluations; and 5) evaluate geologic energy storage resources.
Geologic Carbon Dioxide Utilization Topics
Utilization of other energy-related gases such as CO2, He, nitrogen (N2), and hydrogen sulfide (H2S), if separated and concentrated from the produced natural gas stream, can make otherwise low-thermal (un-economic) natural gas accumulations a viable part of the national natural gas resource base. Many of these gases, including CO2, are separated and vented at the production site (H2S is typically reinjected), thereby contributing greenhouse gas to the atmosphere. Similarly, methane emissions during coal mining and after mine closure are often released to the atmosphere and contribute to greenhouse gases instead of being captured and utilized for energy production. The national electrical grid requires a balance between supply and demand across daily to annual cycles. Subsurface energy storage mechanisms including compressed air or gas, pumped hydroelectric, and geothermal require additional geologic investigations and assessments of available storage resources. To address an all-of-the-above approach, this project works to build improved geologic models needed to describe the distribution and resource-potential of these various energy options.
This task plans to complete a national assessment of He and CO2 resources found in natural gas reservoirs. New field and natural gas geochemistry data collected by task staff will be compiled and interpreted for scientific journal publications. Models of natural CO2 leakage of stored CO2 into shallow aquifers will be developed. A report describing the feasibility of large-scale CO2 mineralization in the United States was completed in 2019. In addition, engineering and economic modeling will be used to better characterize pressure-limited geologic CO2 storage resources. The task will evaluate the datasets and key process steps required to build a probabilistic assessment methodology to assess various geologic subsurface energy storage options that are available for use by the U.S. energy industry.
Subtasks:
- National Helium Resource Assessment: 01-OCT-2017 to 30-SEP-2022 -- Brennan
- Natural CO2 and Helium - Resources and Analogues for Anthropogenic CO2 Storage: 01-OCT-2017 to 30-SEP-2022 -- Brennan
- Feasibility of CO2 Mineralization in the United States: 01-OCT-2017 to 30-SEP-2022 -- Blondes
- Economics of CO2 storage: 01-OCT-2017 to 30-SEP-2020 -- Anderson, Freeman
- Geologic Energy Storage: 01-OCT-2019 to 30-SEP-2022 -- Buursink
Slideshows Associated with Project Member Talks:
- Federal lands greenhouse gas emissions and sequestration – a modified EPA methodology [.pdf]
- A Pressure-limited Model to Estimate CO2 Injection and Storage Capacity of Saline Formations: Investigating the Effects of Formation Properties, Model Variables and Presence of Hydrocarbon Reservoirs [.pdf] [1.2 MB]
- Overview of USGS Carbon Sequestration - Geologic Research and Assessments Project [.pdf] [2.1 MB]
- Status Report: Estimating greenhouse gas emissions from fossil fuels produced from Federal lands [.pdf] [1.2 MB]
- U.S. Geological Survey National Assessment of Geologic Carbon Dioxide Storage Resources and Associated Research [.pdf] [2.3 MB]
- U.S. Geological Survey National Assessment of Geologic Carbon Dioxide Storage Resources and Associated Research [.pdf] [2.6 MB]
- National Assessment of Geologic Carbon Dioxide Storage Resources - Results [.pdf] [2.2 MB]
- U.S. Geological Survey Geologic Carbon Dioxide Storage Resource Assessment of the United States - 2012 Project Update [.pdf] [3.9 MB]
- Examining Salinity Restrictions for CO2 Storage: Suggestions from Basin to Reservoir Scales [.pdf] [1.9 MB]
- Using ArcGIS to Identify Environmental Risk Factors Associated with CO2 Storage [.pdf] [1.7 MB]
- A Probabilistic Assessment Methodology for the Evaluation of Geologic Carbon Dioxide Storage [.pdf] [1.4 MB]
- CO2 Fluid Flow Modeling to Derive the Time Scales of Lateral Fluid Migration [.pdf] [1.2 MB]
- U.S. Geological Survey Geologic Carbon Dioxide Storage Resource Assessment of the United States - Project Update [.pdf] [3.3 MB]
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Below are data or web applications associated with this project task.
Below are multimedia items associated with this project task.
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Geologic framework for the national assessment of carbon dioxide storage resources─South Florida Basin: Chapter L in Geologic framework for the national assessment of carbon dioxide storage resources
Carbon dioxide storage in unconventional reservoirs workshop: summary of recommendations
Geologic framework for the national assessment of carbon dioxide storage resources: Permian and Palo Duro Basins and Bend Arch-Fort Worth Basin: Chapter K in Geologic framework for the national assessment of carbon dioxide storage resources
National assessment of geologic carbon dioxide storage resources: allocations of assessed areas to Federal lands
Fate of injected CO2 in the Wilcox Group, Louisiana, Gulf Coast Basin: Chemical and isotopic tracers of microbial–brine–rock–CO2 interactions
Geologic framework for the national assessment of carbon dioxide storage resources: Williston Basin, Central Montana Basins, and Montana Thrust Belt study areas
Geologic framework for the national assessment of carbon dioxide storage resources: Alaska North Slope and Kandik Basin, Alaska
Geologic framework for the national assessment of carbon dioxide storage resources: U.S. Gulf Coast
Geologic framework for the national assessment of carbon dioxide storage resources: Denver Basin, Colorado, Wyoming, and Nebraska
Significance of carbon dioxide density estimates for basin-scale storage resource assessments
The U. S. Geological Survey carbon dioxide storage efficiency value methodology: Results and observations
Geologic framework for the national assessment of carbon dioxide storage resources: Greater Green River Basin, Wyoming, Colorado, and Utah, and Wyoming-Idaho-Utah Thrust Belt
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- Overview
The objectives of this task are to conduct relevant research needed to 1) evaluate helium (He) and CO2 resources; 2) support future assessments of low-thermal gases and better understand their resources and potential for use as analogues for anthropogenic CO2 storage; 3) study the feasibility of large-scale CO2 mineralization in the United States; 4) develop pressure-limited dynamic models for regional CO2 storage assessments and economic evaluations; and 5) evaluate geologic energy storage resources.
Geologic Carbon Dioxide Utilization TopicsUtilization of other energy-related gases such as CO2, He, nitrogen (N2), and hydrogen sulfide (H2S), if separated and concentrated from the produced natural gas stream, can make otherwise low-thermal (un-economic) natural gas accumulations a viable part of the national natural gas resource base. Many of these gases, including CO2, are separated and vented at the production site (H2S is typically reinjected), thereby contributing greenhouse gas to the atmosphere. Similarly, methane emissions during coal mining and after mine closure are often released to the atmosphere and contribute to greenhouse gases instead of being captured and utilized for energy production. The national electrical grid requires a balance between supply and demand across daily to annual cycles. Subsurface energy storage mechanisms including compressed air or gas, pumped hydroelectric, and geothermal require additional geologic investigations and assessments of available storage resources. To address an all-of-the-above approach, this project works to build improved geologic models needed to describe the distribution and resource-potential of these various energy options.
This task plans to complete a national assessment of He and CO2 resources found in natural gas reservoirs. New field and natural gas geochemistry data collected by task staff will be compiled and interpreted for scientific journal publications. Models of natural CO2 leakage of stored CO2 into shallow aquifers will be developed. A report describing the feasibility of large-scale CO2 mineralization in the United States was completed in 2019. In addition, engineering and economic modeling will be used to better characterize pressure-limited geologic CO2 storage resources. The task will evaluate the datasets and key process steps required to build a probabilistic assessment methodology to assess various geologic subsurface energy storage options that are available for use by the U.S. energy industry.Subtasks:
- National Helium Resource Assessment: 01-OCT-2017 to 30-SEP-2022 -- Brennan
- Natural CO2 and Helium - Resources and Analogues for Anthropogenic CO2 Storage: 01-OCT-2017 to 30-SEP-2022 -- Brennan
- Feasibility of CO2 Mineralization in the United States: 01-OCT-2017 to 30-SEP-2022 -- Blondes
- Economics of CO2 storage: 01-OCT-2017 to 30-SEP-2020 -- Anderson, Freeman
- Geologic Energy Storage: 01-OCT-2019 to 30-SEP-2022 -- Buursink
Slideshows Associated with Project Member Talks:
- Federal lands greenhouse gas emissions and sequestration – a modified EPA methodology [.pdf]
- A Pressure-limited Model to Estimate CO2 Injection and Storage Capacity of Saline Formations: Investigating the Effects of Formation Properties, Model Variables and Presence of Hydrocarbon Reservoirs [.pdf] [1.2 MB]
- Overview of USGS Carbon Sequestration - Geologic Research and Assessments Project [.pdf] [2.1 MB]
- Status Report: Estimating greenhouse gas emissions from fossil fuels produced from Federal lands [.pdf] [1.2 MB]
- U.S. Geological Survey National Assessment of Geologic Carbon Dioxide Storage Resources and Associated Research [.pdf] [2.3 MB]
- U.S. Geological Survey National Assessment of Geologic Carbon Dioxide Storage Resources and Associated Research [.pdf] [2.6 MB]
- National Assessment of Geologic Carbon Dioxide Storage Resources - Results [.pdf] [2.2 MB]
- U.S. Geological Survey Geologic Carbon Dioxide Storage Resource Assessment of the United States - 2012 Project Update [.pdf] [3.9 MB]
- Examining Salinity Restrictions for CO2 Storage: Suggestions from Basin to Reservoir Scales [.pdf] [1.9 MB]
- Using ArcGIS to Identify Environmental Risk Factors Associated with CO2 Storage [.pdf] [1.7 MB]
- A Probabilistic Assessment Methodology for the Evaluation of Geologic Carbon Dioxide Storage [.pdf] [1.4 MB]
- CO2 Fluid Flow Modeling to Derive the Time Scales of Lateral Fluid Migration [.pdf] [1.2 MB]
- U.S. Geological Survey Geologic Carbon Dioxide Storage Resource Assessment of the United States - Project Update [.pdf] [3.3 MB]
- Science
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Below are data or web applications associated with this project task.
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Below are multimedia items associated with this project task.
- Publications
Below are publications associated with this project task.
Filter Total Items: 69Geologic framework for the national assessment of carbon dioxide storage resources─South Florida Basin: Chapter L in Geologic framework for the national assessment of carbon dioxide storage resources
This report presents five storage assessment units (SAUs) that have been identified as potentially suitable for geologic carbon dioxide sequestration within a 35,075-square-mile area that includes the entire onshore and State-water portions of the South Florida Basin. Platform-wide, thick successions of laterally extensive carbonates and evaporites deposited in highly cyclic depositional environmeAuthorsTina L. Roberts-Ashby, Sean T. Brennan, Matthew D. Merrill, Madalyn S. Blondes, P.A. Freeman, Steven M. Cahan, Christina A. DeVera, Celeste D. LohrCarbon dioxide storage in unconventional reservoirs workshop: summary of recommendations
“Unconventional reservoirs” for carbon dioxide (CO2) storage—that is, geologic reservoirs in which changes to the rock trap CO2 and therefore contribute to CO2 storage—including coal, shale, basalt, and ultramafic rocks, were the focus of a U.S. Geological Survey (USGS) workshop held March 28 and 29, 2012, at the National Conservation Training Center in Shepherdstown, West Virginia. The goals of tAuthorsKevin B. Jones, Madalyn S. BlondesGeologic framework for the national assessment of carbon dioxide storage resources: Permian and Palo Duro Basins and Bend Arch-Fort Worth Basin: Chapter K in Geologic framework for the national assessment of carbon dioxide storage resources
The U.S. Geological Survey has completed an assessment of the potential geologic carbon dioxide storage resource in the onshore areas of the United States. To provide geological context and input data sources for the resources numbers, framework documents are being prepared for all areas that were investigated as part of the national assessment. This report is the geologic framework document for tAuthorsMatthew D. Merrill, Ernie R. Slucher, Tina L. Roberts-Ashby, Peter D. Warwick, Madalyn S. Blondes, P.A. Freeman, Steven M. Cahan, Christina A. DeVera, Celeste D. LohrNational assessment of geologic carbon dioxide storage resources: allocations of assessed areas to Federal lands
Following the geologic basin-scale assessment of technically accessible carbon dioxide storage resources in onshore areas and State waters of the United States, the U.S. Geological Survey estimated that an area of about 130 million acres (or about 200,000 square miles) of Federal lands overlies these storage resources. Consequently, about 18 percent of the assessed area associated with storage resAuthorsMarc L. Buursink, Steven M. Cahan, Peter D. WarwickFate of injected CO2 in the Wilcox Group, Louisiana, Gulf Coast Basin: Chemical and isotopic tracers of microbial–brine–rock–CO2 interactions
The “2800’ sandstone” of the Olla oil field is an oil and gas-producing reservoir in a coal-bearing interval of the Paleocene–Eocene Wilcox Group in north-central Louisiana, USA. In the 1980s, this producing unit was flooded with CO2 in an enhanced oil recovery (EOR) project, leaving ∼30% of the injected CO2 in the 2800’ sandstone post-injection. This study utilizes isotopic and geochemical tracerAuthorsJenna L. Shelton, Jennifer C. McIntosh, Peter D. Warwick, Amelia Lee Zhi YiGeologic framework for the national assessment of carbon dioxide storage resources: Williston Basin, Central Montana Basins, and Montana Thrust Belt study areas
The 2007 Energy Independence and Security Act directs the U.S. Geological Survey (USGS) to conduct a national assessment of potential geologic storage resources for carbon dioxide (CO2). The methodology used by the USGS for the national CO2 assessment follows that of previous USGS work. This methodology is non-economic and is intended to be used at regional to sub-basinal scales. The Williston BasAuthorsMarc L. Buursink, Matthew D. Merrill, William H. Craddock, Tina L. Roberts-Ashby, Sean T. Brennan, Madalyn S. Blondes, P.A. Freeman, Steven M. Cahan, Christina A. DeVera, Celeste D. LohrGeologic framework for the national assessment of carbon dioxide storage resources: Alaska North Slope and Kandik Basin, Alaska
This report presents fourteen storage assessment units (SAUs) from the Alaska North Slope and two SAUs from the Kandik Basin of Alaska. The Alaska North Slope is a broad, north-dipping coastal plain that is underlain by a thick succession of sedimentary rocks that accumulated steadily throughout much of the Phanerozoic during three major tectonic sequences: the Mississippian through Triassic EllesAuthorsWilliam H. Craddock, Marc L. Buursink, Jacob A. Covault, Sean T. Brennan, Colin A. Doolan, Ronald M. Drake, Matthew D. Merrill, Tina L. Roberts-Ashby, Ernie R. Slucher, Peter D. Warwick, Madalyn S. Blondes, P.A. Freeman, Steven M. Cahan, Christina A. DeVera, Celeste D. LohrGeologic framework for the national assessment of carbon dioxide storage resources: U.S. Gulf Coast
This report presents 27 storage assessment units (SAUs) within the United States (U.S.) Gulf Coast. The U.S. Gulf Coast contains a regionally extensive, thick succession of clastics, carbonates, salts, and other evaporites that were deposited in a highly cyclic depositional environment that was subjected to a fluctuating siliciclastic sediment supply and transgressive and regressive sea levels. AtAuthorsTina L. Roberts-Ashby, Sean T. Brennan, Marc L. Buursink, Jacob A. Covault, William H. Craddock, Ronald M. Drake, Matthew D. Merrill, Ernie R. Slucher, Peter D. Warwick, Madalyn S. Blondes, Mayur A. Gosai, P.A. Freeman, Steven M. Cahan, Christina A. DeVera, Celeste D. LohrGeologic framework for the national assessment of carbon dioxide storage resources: Denver Basin, Colorado, Wyoming, and Nebraska
This is a report about the geologic characteristics of five storage assessment units (SAUs) within the Denver Basin of Colorado, Wyoming, and Nebraska. These SAUs are Cretaceous in age and include (1) the Plainview and Lytle Formations, (2) the Muddy Sandstone, (3) the Greenhorn Limestone, (4) the Niobrara Formation and Codell Sandstone, and (5) the Terry and Hygiene Sandstone Members. The describAuthorsRonald M. Drake, Sean T. Brennan, Jacob A. Covault, Madalyn S. Blondes, P.A. Freeman, Steven M. Cahan, Christina A. DeVera, Celeste D. LohrSignificance of carbon dioxide density estimates for basin-scale storage resource assessments
The geologic carbon dioxide (CO2) storage resource size is a function of the density of CO2 in the subsurface. The pressure and temperature of the storage reservoir at depth affect the CO2 density. Therefore, knowing these subsurface conditions allows for improved resource estimates of potential geologic CO2 storage capacity. In 2012, the U.S. Geological Survey (USGS) completed an assessment of geAuthorsMarc L. BuursinkThe U. S. Geological Survey carbon dioxide storage efficiency value methodology: Results and observations
In order to complete the 2013 U.S. Geological Survey (USGS) assessment of carbon dioxide (CO2) storage resources, a methodology was needed to determine the CO2storage efficiency of individual rock strata. The method that was used involved a storage efficiency approximation by MacMinn et al., combined with a brine viscosity model by Mao and Duan, and thermal and pressure data from petroleum fieldsAuthorsSean T. BrennanGeologic framework for the national assessment of carbon dioxide storage resources: Greater Green River Basin, Wyoming, Colorado, and Utah, and Wyoming-Idaho-Utah Thrust Belt
The 2007 Energy Independence and Security Act (Public Law 110–140) directs the U.S. Geological Survey (USGS) to conduct a national assessment of potential geologic storage resources for carbon dioxide (CO2). The methodology used by the USGS for the national CO2 assessment follows up on previous USGS work. The methodology is non-economic and intended to be used at regional to subbasinal scales. ThiAuthorsMarc L. Buursink, Ernie R. Slucher, Sean T. Brennan, Colin A. Doolan, Ronald M. Drake, Matthew D. Merrill, Peter D. Warwick, Madalyn S. Blondes, P.A. Freeman, Steven M. Cahan, Christina A. DeVera, Celeste D. Lohr - Web Tools
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