Vanessa Nuñez-Lopez

The system-wide economics of a carbon dioxide capture, utilization, and storage network: Texas Gulf Coast with pure CO2-EOR flood

This letter compares several bounding cases for understanding the economic viability of capturing large quantities of anthropogenic CO2 from coal-fired power generators within the Electric Reliability Council of Texas electric grid and using it for pure CO2 enhanced oil recovery (EOR) in the onshore coastal region of Texas along the Gulf of Mexico. All captured CO2 in excess of that needed for EOR is sequestered in saline formations at the same geographic locations as the oil reservoirs but at a different depth. We analyze the extraction of oil from the same set of ten reservoirs within 20- and five-year time frames to describe how the scale of the carbon dioxide capture, utilization, and storage (CCUS) network changes to meet the rate of CO2 demand for oil recovery. Our analysis shows that there is a negative system-wide net present value (NPV) for all modeled scenarios. The system comes close to breakeven economics when capturing CO2 from three coal-fired power plants to produce oil via CO2-EOR over 20 years and assuming no CO2 emissions penalty. The NPV drops when we consider a larger network to produce oil more quickly (21 coal-fired generators with CO2 capture to produce 80% of the oil within five years). Upon applying a CO2 emissions penalty of 60

Source-Sink Matching and Potential for Carbon Capture and Storage in the Gulf Coast

2009/tCO2 to fossil fuel emissions to ensure that coal-fired power plants with CO2 capture remain in baseload operation, the system economics drop significantly. We show near profitability for the cash flow of the EOR operations only; however, this situation requires relatively cheap electricity prices during operation.

Geologic factors controlling CO2 storage capacity and permanence: case studies based on experience with heterogeneity in oil and gas reservoirs applied to CO2 storage

Current global levels of anthropogenic CO2 emissions are 25.6 Gigatons yr. Approximately 1 Gigaton comes from the Texas, Louisiana, and Mississippi Gulf Coast, representing 16 percent of the U.S. annual CO2 emissions from fossil fuels. The Gulf Coast region provides an opportunity for addressing the problem. Geologic sequestration results from the capturing of CO2 from combustion products and injecting the compressed gas as a supercritical fluid into subsurface brine aquifers for long-term storage. The Gulf Coast overlies an unusually thick succession of highly porous and permeable sand aquifers separated by thick shale aquitards. The Gulf Coast also has a large potential for enhanced oil recovery (EOR), in which CO2 injected into suitable oil reservoirs could be used first for EOR and then for large-volume, long-term storage of CO2 in nonproductive formations below the reservoir interval. For example, there are numerous opportunities for locating CO2 injection wells either in fields for EOR or in stacked brine aquifers near potential FutureGen sites, where a near-zero emission facility would generate primarily hydrogen and CO2 as by-products. We estimate that in the Gulf Coast, outside of the traditional area of CO2 EOR in the Permian Basin, an additional 4.5 billion barrels of oil could be produced by using miscible CO2. At

Quick-look assessments to identify optimal CO2 EOR storage sites

60 per barrel, this incremental production is estimated to have a wellhead value of

CO2 source-sink matching in the lower 48 United States, with examples from the Texas Gulf Coast and Permian Basin.

270 billion that could generate more than

Temperature monitoring using Distributed Temperature Sensing (DTS) technology

40 billion in taxes.