Evaluating the Climate Benefits of CO<sub>2</sub>-Enhanced Oil Recovery Using Life Cycle Analysis

Cooney, Gregory J.; Littlefield, James; Marriott, Joe; Skone, Timothy J

doi:10.1021/acs.est.5b00700

Cited by 93 publications

(59 citation statements)

References 9 publications

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“…Most carbon lifecycle analyses use an average for EOR/storage efficiency in their calculations, but as demonstrated here, CO2 utilization rates vary significantly throughout the operation; such simplifications affect carbon balance results. Cooney et al [13], acknowledged this as a potential improvement, which we have accomplished in this study. A better indicator of the efficiency of the CO 2 -EOR floods are the CO 2 utilization rates ( Figure 5), which refer to the volume of CO 2 that needs to be injected to produce one barrel of oil.…”

Section: Scenarios Without Stacked Carbon Storage In Saline Aquifersmentioning

confidence: 67%

Section: Scenarios Without Stacked Carbon Storage In Saline Aquifersmentioning

confidence: 67%

“…We assumed a maximum pipeline transportation distance of 300 miles from the Cranfield field to the closest concentration of refineries in the USA This cluster refines about 75% of the total crude oil processed in the USA Gulf Coast area. Based on Cooney et al [13], we assumed that USA crude oil is transported from the field to the refineries with an energy intensity of 260 BTU/tonne-mile or 189 J/kg-Km. We also assumed that this energy is 100% supplied by the local grid (SRMV).…”

Section: Carbon Emission Estimates Downstream Of the Co 2 -Eor Sitementioning

confidence: 99%

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Environmental and Operational Performance of CO2-EOR as a CCUS Technology: A Cranfield Example with Dynamic LCA Considerations

2019

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This study evaluates the potential of carbon dioxide-enhanced oil recovery (CO2-EOR) to reduce greenhouse gas emissions without compromising oil production goals. A novel, dynamic carbon lifecycle analysis (d-LCA) was developed and used to understand the evolution of the environmental impact (CO2 emissions) and mitigation (geologic CO2 storage) associated with an expanded carbon capture, utilization and storage (CCUS) system, from start to closure of operations. EOR operational performance was assessed through CO2 utilization rates, which relate usage of CO2 to oil production. Because field operational strategies have a significant impact on reservoir engineering parameters that affect both CO2 storage and oil production (e.g., sweep efficiency, flood conformance, fluid saturation distribution), we conducted a scenario analysis that assessed the operational and environmental performance of four common and novel CO2-EOR field development strategies. Each scenario was evaluated with and without stacked saline carbon storage, an EOR/storage combination strategy where excess CO2 from the recycling facility is injected into an underlying saline aquifer for long-term carbon storage. The dynamic interplay between operational and environmental performance formed the basis of our CCUS technology analysis. The results showed that all CO2-EOR evaluated scenarios start operating with a negative carbon footprint and, years into the project, transitioned into operating with a positive carbon footprint. The transition points were significantly different in each scenario. Water-alternating-gas (WAG) was identified as the CO2 injection strategy with the highest potential to co-optimize EOR and carbon storage goals. The results provide an understanding of the evolution of the system’s net carbon balance in all four field development strategies studied. The environmental performance can be significantly improved with stacked storage, where a negative carbon footprint can be maintained throughout the life of the operation in most of the injection scenarios modelled. This information will be useful to CO2-EOR operators seeking value in storing more CO2 through a carbon credit program (e.g., the 45Q carbon credit program in the USA). Most importantly, this study serves as confirmation that CO2-EOR can be operationally designed to both enhance oil production and reduce greenhouse gas emissions into the atmosphere.

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Section: Scenarios Without Stacked Carbon Storage In Saline Aquifersmentioning

confidence: 67%

Section: Scenarios Without Stacked Carbon Storage In Saline Aquifersmentioning

confidence: 67%

Section: Carbon Emission Estimates Downstream Of the Co 2 -Eor Sitementioning

confidence: 99%

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Environmental and Operational Performance of CO2-EOR as a CCUS Technology: A Cranfield Example with Dynamic LCA Considerations

2019

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“…This study assessed the overall life cycle emissions associated with sequestration via CO 2 -flood EOR under a number of different scenarios and explored the impact of various methods for allocating CO 2 system emissions and the benefits of sequestration [15]. Hussain et al (2013) and Cooney et al (2015) used hypothetical reservoir models to evaluate GHG emissions for CO 2 -EOR based on various CO 2 sources, including conventional CO 2 sources (e.g., natural source, coal synthetic natural gas (SNG) plant) and alternative CO 2 sources (e.g., coal IGCC, switch grass IGCC, natural gas combined cycle (NGCC), and biogas NGCC). And they also carried out sensitivity analysis for the range of EOR parameters [16][17].…”

Section: Literature Reviewmentioning

confidence: 99%

“…Hussain et al (2013) and Cooney et al (2015) used hypothetical reservoir models to evaluate GHG emissions for CO 2 -EOR based on various CO 2 sources, including conventional CO 2 sources (e.g., natural source, coal synthetic natural gas (SNG) plant) and alternative CO 2 sources (e.g., coal IGCC, switch grass IGCC, natural gas combined cycle (NGCC), and biogas NGCC). And they also carried out sensitivity analysis for the range of EOR parameters [16][17]. Hussain et al (2013) used a process lifecycle inventory (LCI) to compare the lifecycle greenhouse gas (GHG) emissions of enhanced oil recovery (EOR) operations using different sources for CO 2 and to non-CO 2 EOR methods [16].…”

Section: Literature Reviewmentioning

confidence: 99%

Life Cycle CO2 Emission Estimation of CCS-EOR System Using Different CO2 Sources

Jiang¹,

Lei²,

Yang³

et al. 2018

Pol. J. Environ. Stud.

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Molecular dynamics of CH₄/CO₂ on calcite for enhancing gas recovery

et al. 2022

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The effect of temperature and pressure on the adsorption of CO 2 and CH 4 gases on calcite (104) has been studied by means of classical molecular dynamics. The results show that carbon dioxide greatly improves methane desorption in the 323-373 K range, even at low CO 2 concentrations. However, this effect is less pronounced for very high temperatures (423 K), where most of the methane is desorbed and CO 2 tends to desorb in large quantities. Radial distribution function (RDF) analysis reveals two distinct peaks for CO 2 (0.36 and 0.47 nm) and two for methane (0.87 and 0.57 nm) and the intensities of these peaks tend to decrease with increasing temperature. Such peaks are always clearly visible for CO 2, while the methane profile gets very broad already for mild conditions of temperature and CO 2 concentration. These results highlight how the CO 2

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Evaluating the Climate Benefits of CO₂-Enhanced Oil Recovery Using Life Cycle Analysis

Cited by 93 publications

References 9 publications

Environmental and Operational Performance of CO2-EOR as a CCUS Technology: A Cranfield Example with Dynamic LCA Considerations

Environmental and Operational Performance of CO2-EOR as a CCUS Technology: A Cranfield Example with Dynamic LCA Considerations

Life Cycle CO2 Emission Estimation of CCS-EOR System Using Different CO2 Sources

Molecular dynamics of CH₄/CO₂ on calcite for enhancing gas recovery

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Evaluating the Climate Benefits of CO2-Enhanced Oil Recovery Using Life Cycle Analysis

Cited by 93 publications

References 9 publications

Environmental and Operational Performance of CO2-EOR as a CCUS Technology: A Cranfield Example with Dynamic LCA Considerations

Environmental and Operational Performance of CO2-EOR as a CCUS Technology: A Cranfield Example with Dynamic LCA Considerations

Life Cycle CO2 Emission Estimation of CCS-EOR System Using Different CO2 Sources

Molecular dynamics of CH4/CO2 on calcite for enhancing gas recovery

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Product

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About

Evaluating the Climate Benefits of CO₂-Enhanced Oil Recovery Using Life Cycle Analysis

Molecular dynamics of CH₄/CO₂ on calcite for enhancing gas recovery