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Large-scale deployment (i.e.,, nationwide) of Carbon Capture and Storage (CCS) technology will play a key role in carbon storage removal (CDR) and overall climate mitigation efforts. The economic feasibility of large-scale CCS deployments partly depends on the CO2 storage costs per project. However, the suitability of regional storage and injectivity per project, particularly for large-scale purposes, is not well understood. This study focuses on two concepts that augments existing studies of storage capacity and cost to assess the opportunities and barriers to CDR. The first concept focuses on identifying all potential areas for CO2 storage within the sedimentary rocks throughout the U.S. based on a novel concept we call the CO2 Storage Window. The second concept focuses on improving CO2 storage costs estimates by considering 1) the number of wells needed to inject at a certain rate, dependent on injectivity of the area and 2) the areal extent of pressure build-up caused by CO2 injection. This area extent is a novel concept we call pressure space. Understanding the pressure space of a project helps delineate the area of review for a project and the extent of the pore space required for the project. The results of this study include a spatial geodatabase and a series of U.S. cohesive, spatial distribution maps showcasing 1) CO2 storage potential in areas not explored before, 2) Storage costs per CCS project and storage costs per ton of CO2, assuming a constant maximum storage capacity of 20 Mt per project over a 20-year timeframe, and 3) Estimated storage costs per ton of CO2 in areas where storage potential is found but where there is not enough data to calculate capacity nor injectivity
Carbon dioxide capture and storage (CCS) is a technology aimed at reducing greenhouse gas emissions from burning fossil fuels during industrial and energy-related processes. CCS involves the capture, transport and long-term storage of carbon dioxide, usually in geological reservoirs deep underground that would otherwise be released to the atmosphere. Carbon dioxide capture and storage offers important possibilities for making further use of fossil fuels more compatible with climate change mitigation policies. The largest volumes of CO2 could be captured from large point sources such as from power generation, which alone accounts for about 40 per cent of total anthropogenic CO2 emissions. The development of capture technologies in the power generation sector could be particularly important in view of the projected increase in demand for electricity in fast developing countries with enormous coal reserves (IEA 2002a). Although, this prospect is promising, more research is needed to overcome several hurdles such as important costs of capture technology and the match of large capture sources with adequate geological storage sites. The book will provide a comprehensive, detailed but non-specialist overview of the wide range of technologies involved in carbon dioxide capture and sequestration. Focuses on technology rather than regulation and cost Covers both traditional and cutting edge capture technology Contains an abundance of case-studies an worked out examples Insight into CSS technical processes
Published by the American Geophysical Union as part of the Geophysical Monograph Series, Volume 183. For carbon sequestration the issues of monitoring, risk assessment, and verification of carbon content and storage efficacy are perhaps the most uncertain. Yet these issues are also the most critical challenges facing the broader context of carbon sequestration as a means for addressing climate change. In response to these challenges, Carbon Sequestration and Its Role in the Global Carbon Cycle presents current perspectives and research that combine five major areas: The global carbon cycle and verification and assessment of global carbon sources and sinks Potential capacity and temporal/spatial scales of terrestrial, oceanic, and geologic carbon storage Assessing risks and benefits associated with terrestrial, oceanic, and geologic carbon storage Predicting, monitoring, and verifying effectiveness of different forms of carbon storage Suggested new CO2 sequestration research and management paradigms for the future. The volume is based on a Chapman Conference and will appeal to the rapidly growing group of scientists and engineers examining methods for deliberate carbon sequestration through storage in plants, soils, the oceans, and geological repositories.
Deployment of Carbon Capture and Storage: Insights, Case Studies and Best Practices presents the latest research and technologies on Carbon Capture and Storage (CCS), building on the topics to provide case studies and lesson learned from early stage projects. The book highlights CCS storage technologies deployed at scale to offer readers insights and guidance that will ensure they make sound decisions when developing CCS programs. Cost and risk minimization techniques are included to minimize cost and risk for wide-scale commercial deployment required by 2050. Global case studies on CCS technology and high TLR provide readers with unique insight into worldwide activity. Readers will gain a thorough understanding of the full CCS chain as applied across multiple settings including energy, chemical, geological and environmental industries, as well as an authoritative understanding of international policy and regulation factors. Includes an international case study from a variety of regions that provides insights and context to topics discussed Promotes best practices that support readers in their decision-making Includes high TRL technology insights, focusing on technologies reaching commercial deployment to achieve 2050 sustainability targets
To achieve goals for climate and economic growth, "negative emissions technologies" (NETs) that remove and sequester carbon dioxide from the air will need to play a significant role in mitigating climate change. Unlike carbon capture and storage technologies that remove carbon dioxide emissions directly from large point sources such as coal power plants, NETs remove carbon dioxide directly from the atmosphere or enhance natural carbon sinks. Storing the carbon dioxide from NETs has the same impact on the atmosphere and climate as simultaneously preventing an equal amount of carbon dioxide from being emitted. Recent analyses found that deploying NETs may be less expensive and less disruptive than reducing some emissions, such as a substantial portion of agricultural and land-use emissions and some transportation emissions. In 2015, the National Academies published Climate Intervention: Carbon Dioxide Removal and Reliable Sequestration, which described and initially assessed NETs and sequestration technologies. This report acknowledged the relative paucity of research on NETs and recommended development of a research agenda that covers all aspects of NETs from fundamental science to full-scale deployment. To address this need, Negative Emissions Technologies and Reliable Sequestration: A Research Agenda assesses the benefits, risks, and "sustainable scale potential" for NETs and sequestration. This report also defines the essential components of a research and development program, including its estimated costs and potential impact.
Geological storage and sequestration of carbon dioxide, in saline aquifers, depleted oil and gas fields or unminable coal seams, represents one of the most important processes for reducing humankind’s emissions of greenhouse gases. Geological storage of carbon dioxide (CO2) reviews the techniques and wider implications of carbon dioxide capture and storage (CCS). Part one provides an overview of the fundamentals of the geological storage of CO2. Chapters discuss anthropogenic climate change and the role of CCS, the modelling of storage capacity, injectivity, migration and trapping of CO2, the monitoring of geological storage of CO2, and the role of pressure in CCS. Chapters in part two move on to explore the environmental, social and regulatory aspects of CCS including CO2 leakage from geological storage facilities, risk assessment of CO2 storage complexes and public engagement in projects, and the legal framework for CCS. Finally, part three focuses on a variety of different projects and includes case studies of offshore CO2 storage at Sleipner natural gas field beneath the North Sea, the CO2CRC Otway Project in Australia, on-shore CO2 storage at the Ketzin pilot site in Germany, and the K12-B CO2 injection project in the Netherlands. Geological storage of carbon dioxide (CO2) is a comprehensive resource for geoscientists and geotechnical engineers and academics and researches interested in the field. Reviews the techniques and wider implications of carbon dioxide capture and storage (CCS) An overview of the fundamentals of the geological storage of CO2 discussing the modelling of storage capacity, injectivity, migration and trapping of CO2 among other subjects Explores the environmental, social and regulatory aspects of CCS including CO2 leakage from geological storage facilities, risk assessment of CO2 storage complexes and the legal framework for CCS
On March 27, 2012, the U.S. Environmental Protection Agency (EPA) proposed a new rule that would limit emissions to no more than 1,000 pounds of carbon dioxide (CO2) per megawatt-hour of production from new fossil-fuel power plants with a capacity of 25 megawatts or larger. EPA proposed the rule under Section 111 of the Clean Air Act. According to EPA, new natural gas fired combined-cycle power plants should be able to meet the proposed standards without additional cost. However, new coal-fired plants would only be able to meet the standards by installing carbon capture and sequestration (CCS) technology. The proposed rule has sparked increased scrutiny of the future of CCS as a viable technology for reducing CO2 emissions from coal-fired power plants. The proposed rule also places a new focus on whether the U.S. Department of Energy's (DOE's) CCS research, development, and demonstration (RD&D) program will achieve its vision of developing an advanced CCS technology portfolio ready by 2020 for large-scale CCS deployment. Congress has appropriated nearly $6 billion since FY2008 for CCS RD&D at DOE's Office of Fossil Energy: approximately $2.3 billion from annual appropriations and $3.4 billion from the American Recovery and Reinvestment Act (or Recovery Act). The large and rapid influx of funding for industrial-scale CCS projects from the Recovery Act may accelerate development and deployment of CCS in the United States. However, the future deployment of CCS may take a different course if the major components of the DOE program follow a path similar to DOE's flagship CCS demonstration project, FutureGen, which has experienced delays and multiple changes of scope and design since its inception in 2003. A question for Congress is whether FutureGen represents a unique case of a first mover in a complex, expensive, and technically challenging endeavor, or whether it indicates the likely path for all large CCS demonstration projects once they move past the planning stage. Since enactment of the Recovery Act, DOE has shifted its RD&D emphasis to the demonstration phase of carbon capture technology. The shift appears to heed recommendations from many experts who called for large, industrial-scale carbon capture demonstration projects (e.g., 1 million tons of CO2 captured per year). Funding from the Recovery Act for large-scale demonstration projects was 40% of the total amount of DOE funding for all CCS RD&D from FY2008 through FY2012. To date, there are no commercial ventures in the United States that capture, transport, and inject industrial-scale quantities of CO2 solely for the purposes of carbon sequestration. However, CCS RD&D in 2012 is just now embarking on commercial-scale demonstration projects for CO2 capture, injection, and storage. The success of these projects will likely bear heavily on the future outlook for widespread deployment of CCS technologies as a strategy for preventing large quantities of CO2 from reaching the atmosphere while U.S. power plants continue to burn fossil fuels, mainly coal. Given the pending EPA rule, congressional interest in the future of coal as a domestic energy source appears directly linked to the future of CCS. In the short term, congressional support for building new coal-fired power plants could be expressed through legislative action to modify or block the proposed EPA rule. Alternatively, congressional oversight of the CCS RD&D program could help inform decisions about the level of support for the program and help Congress gauge whether it is on track to meet its goals.
This book introduces the scientific basis and engineering practice for CO2 storage, covering topics such as storage capacity, trapping mechanisms, CO2 phase behaviour and flow dynamics, engineering and geomechanics of geological storage, injection well design, and geophysical and geochemical monitoring. It also provides numerous examples from the early mover CCS projects, notably Sleipner and Snøhvit offshore Norway, as well as other pioneering CO2 storage projects.