Carbon Storage Technology Manager
National Energy Technology Laboratory
3610 Collins Ferry Road
P.O. Box 880
Morgantown, WV 26507
National Energy Technology Laboratory
P.O. Box 10940
Pittsburgh, PA 15236
Lawrence Livermore National Laboratory
P.O. Box 808
Livermore, CA 94551
DOE Share: $10,729,000.00
Performer Share: $2,400,000.00
Total Award Value: $13,129,000.00
Performer website: Lawrence Livermore National Laboratory - http://www.llnl.gov
Lawrence Livermore National Laboratory is working to advance the existing state of geological sequestration technologies by collaborating with several other national laboratories, industrial partners, and universities to complete a series of five distinct and unique tasks. Each task is focused on advancing a critical component needed for successful geologic storage of CO2. A detailed description of each task is listed below:
National Risk Assessment Program Collaboration Research: LLNL is working with NETL, Los Alamos National Laboratory (LANL), Lawrence Berkeley National Laboratory (LBNL), and Pacific Northwest National Laboratory (PNNL) to perform collaborative and coordinated research to enhance the nation’s capabilities for science-based risk assessment for geologic carbon sequestration. Research tasks are focused on monitoring for risk assessment, well integrity, pathways through natural systems, groundwater impacts, and systems modeling for risk assessment. Ensuring that geologic CO2 storage is safe and effective will require site-specific quantitative risk assessment, which combines performance assessment of a storage site (i.e., prediction of the fate and impact of the stored CO2) with an assessment of potential consequences of concern (e.g., environmental, health, economic).
Fresh Water Generation from Storage Formation Pressured Carbon Storage: The Fresh Water Generation task establishes the potential for using brine pressurized by CCS injection operations in saline formations as the feedstock for desalination and water treatment technologies, including nanofiltration and reverse osmosis. This method uses the energy required to inject CO2 into the subsurface to provide all or part of the inlet pressure for the desalination system. This process improves sequestration by providing additional storage space (capacity) in the reservoir, as well as providing low-cost fresh water to offset costs or operational water needs. It also reduces operational risks by relieving long-term pressure growth in the formation.
Injection and Reservoir Hazard Management - The Role of Injection-Induced Mechanical Deformation and Geochemical Alteration at In Salah CO2 Storage Project: The In Salah project provides an opportunity to study key physical and chemical processes in operational deployment of geological carbon sequestration from natural gas production in eight fields in the Algerian Central Sahara. In Salah has been successful at minimizing the associated environmental footprint by capturing and storing excess CO2 extracted from natural gas production streams. The objectives of the research are to study two components relevant to storage effectiveness and operational success at In Salah: (1) reactive chemistry of the brine-CO2-reservoir-caprock-wellbore system, and (2) the geomechanical effects of large-scale injection on crustal deformation and fault leakage hazards. Results from this work will enhance predictive capability of field performance, provide a new basis for interpretation of geophysical monitoring at In Salah, and provide additional information relevant to the creation of geological sequestration standards.
Carbon Sequestration Support to Collaborative Efforts in China: LLNL will work in collaboration with NETL and West Virginia University to provide technical support for a potential CCS project for Shenhua Direct Coal Liquefaction (DLC). The work includes assessment and identification of CCS potential within the Ordos Basin, an estimate of the fate of stored CO2 using reactive transport simulators and geologic models based on available literature, and consideration of monitoring and verification needs and potential technologies. LLNL will also contribute to topical reports requested by DOE and Shenhua DLC.
Snøhvit CO2 Storage Project - Understanding the role of injection-induced mechanical deformation and directed sea-floor monitoring: The Snøhvit project is the first petroleum production plant to be located in the Barents Sea. At the onshore liquefied natural gas plant, CO2 is separated from the production stream to make the product suitable for compression and export. Separated CO2 is then sequestered below Snøhvit at rates up to 700,000 tons of CO2 per year. Large-scale commercial CO2 injections face several new technical challenges in development and operations, including pressure build-up caused by the large-volume CO2 injection and associated stress issues. This stress can lead to potential leakage pathways. Another issue is the operational challenge of monitoring the sea-floor. Many common surface detection methods for detecting CO2 fluxes will not work in the deep sea environment or be deployed easily and economically. This creates challenges for the appropriate stewardship and environmental protection of large projects as required by important stakeholders and international maritime agreements. LLNL will study two components relevant to storage effectiveness and operational success: (1) the geomechanical effects of injection on rock deformation and fault leakage hazards, and (2) guidance on developing a monitoring program focused on possible migration of CO2 and brines to the seafloor. Results from this work will enhance the predictive capability of field performance models, provide a new basis for interpretation of geo-physical and operational data at Snøhvit, and provide support for the creation of appropriate regulations and monitoring schemes for sub-sea geological storage of CO2.
Program Background and Project Benefits
The U.S. Department of Energy’s (DOE) National Energy Technology Laboratory (NETL) is helping to develop carbon capture and storage (CCS) technologies to capture, separate, and store carbon dioxide (CO2) in order to reduce green-house gas emissions without adversely influencing energy use or hindering economic growth. Carbon sequestration technologies capture and store CO2 by injecting and permanently storing it in underground geologic formations.
NETL is working to advance geologic carbon sequestration technology by funding research projects that aim to accelerate deployment and remove barriers to commercial-scale carbon sequestration. Lawrence Livermore National Laboratory (LLNL), one of DOE’s national laboratories for science and engineering research, is working in conjunction with several other national laboratories, industry partners, and universities on a series of individual tasks aimed at advancing the state-of-thescience of geologic sequestration by conducting research studies on key topics critical to the success of geologic sequestration. Research areas include sequestration monitoring for risk assessment, brine production and beneficial use, pathways through natural systems, groundwater impacts, collaboration with international CCS efforts, and systems modeling for risk assessment.
LLNL and its partners will perform collaborative and coordinated research to enhance the nation’s capabilities for science-based risk assessment for geologic carbon sequestration. This project combines fundamental geological sequestration research and commercial-scale international programs with risk and hazard management projects to address key issues affecting commercial-scale carbon storage.
The expected project impacts and benefits are to provide fundamental research and application technologies leading to commercial-scale deployment and to make contributions to and gain insight from international CCS efforts. This research addresses specific technical issues raised during ongoing field projects; leverages and coordinates experiences, resources, and capabilities of the national laboratories as applied to CCS; and reduce the overall risk of large demonstration projects. Most importantly, the work provides a scientific basis for both understanding important scientific concepts critical to the success of CCS and risk assessments for demonstration projects leading toward commercial-scale deployment.