A metric for evaluating conformance robustness during geologic CO2 sequestration operations

Harp, Dylan R.; Oldenburg, Curtis M.; Pawar, Rajesh J.

doi:10.1016/j.ijggc.2019.03.023

Cited by 12 publications

(5 citation statements)

References 45 publications

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“…Despite fairly significant deviations from the actual model, the 5-year ORM produced a gross-scale match of the actual gas saturation that turned out sufficient for the bound construction and ensuing delineation of anticipated target zones. A follow-up study similar to Harp et al (2019) would investigate at what point larger deviations, caused by larger ORM parameter errors, would render the BSEM imaging outcome too distorted. Harp et al (2019) developed a metric for quantifying the degree to which ORM parameters can deviate from their actuals without violating preset reservoir performance criteria.…”

Section: Discussionmentioning

confidence: 99%

“…A follow-up study similar to Harp et al (2019) would investigate at what point larger deviations, caused by larger ORM parameter errors, would render the BSEM imaging outcome too distorted. Harp et al (2019) developed a metric for quantifying the degree to which ORM parameters can deviate from their actuals without violating preset reservoir performance criteria. We envision a similar kind of robustness measure for assessing when an ORM may become too erroneous for properly constraining geophysical reservoir imaging.…”

Section: Discussionmentioning

confidence: 99%

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Improved geophysical monitoring of carbon sequestration through parameter linkage to reservoir modeling

Commer

Gasperikova

Doughty

2022

International Journal of Greenhouse Gas Control

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Improved geophysical monitoring of carbon sequestration through parameter linkage to reservoir modeling

Commer

Gasperikova

Doughty

2022

International Journal of Greenhouse Gas Control

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“…Some of the major potential hazards related to the underground storage of CO2 include the leakage of CO2 from the storage unit, induced seismic activity, significant ground deformation and well damage. Various cases have since been reported in which earthquakes were caused by the production and injection of gas or water in the underground storage sites [1][2][3][4]. There have been some attempts to describe the procedure leading to the seismicity in hydrocarbon production fields [5][6].…”

Section: Introductionmentioning

confidence: 99%

Geomechanical effects of co2 storage in geological structures: two case studies

Soltanzadeh

Hakim

Ibrahim

et al. 2022

IJET

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Storage of CO2 in subsurface can assist to mitigate CO2 emission without extensively interfering with industrial activity and development. The main reason for geological storage to trap CO2 underground for a long time. However, the injection of CO2 may compromise the sealing characteristics of the caprock and, consequently, the containment of the underground CO2 storage unit as well. For instance, the injection of CO2 into a reservoir resulted in pore pressure and temperature changes leading to deformation and stress changes in the injection target and the rocks that surround it. These changes can influence the hydraulic integrity of the geological storage. The potential hazards could then impose different environmental, health, safety, and economic risks. Therefore, the geomechanical assessment of caprock integrity is critical for the storage of carbon dioxide. This research reviewed two different cases of underground CO2 storage in Canada and the workflows used for the assessment of geomechanical effects of CO2 injection on caprock integrity. It reviewed the processes of data collection, geomechanical characterization, and fluid flow modeling. These reviews highlighted the significance of geomechanical characterization and the fact that it is faced with significance challenges that could be addressed by data integration and geostatistical analysis. These reviewed studies implemented both analytical and numerical geomechanical models. While analytical models seem to be great choices for preliminary geomechanical analysis, numerical models are also necessary for a more detailed analysis.Â Â

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“…In terms of regulators and stakeholders, a conforming GCS project is a successful GCS project. Nevertheless, as with all subsurface technologies, there is uncertainty involved in the assessment of conformance, and this uncertainty must be understood in order to understand the robustness of conformance assessment (e.g., Harp et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

CO2 plume evolution in a depleted natural gas reservoir: Modeling of conformance uncertainty reduction over time

Doughty

Oldenburg

2020

International Journal of Greenhouse Gas Control

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Uncertainty in the long-term fate of CO2 injected for geologic carbon sequestration (GCS) is a significant barrier to the adoption of GCS as a greenhouse-gas emission-mitigation for industry and regulatory agencies alike. We present a modeling study that demonstrates that the uncertainty in forecasts of GCS site performance decreases over time as monitoring data are used to update operational models. We consider a case study of GCS in a depleted natural gas reservoir, with CO2 injection occurring over 20 years, with a 50-year post-injection site care period. We constructed a detailed model to generate the actual model output, which is considered synthetic observation data. A series of simpler operational models based on limited data and assumptions about how an operator would model such a site are then run and compared against actual model output at specific monitoring points after one year, two years, etc. The operational model is updated and improved using the synthetic observation data from the actual model at the same time intervals. Model parameter values and model features needed to be updated over time to improve matches to the actual model. These kinds of model adjustments would be a normal part of reservoir engineering and site management at GCS sites. Uncertainty in two key measures related to site performance decreases with time: extent of the CO2 plume up-dip migration, and radial extent of the pressure pulse. This conclusion should help allay the concerns of industry and regulators about uncertainty in long-term fate of CO2 at GCS sites.

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A metric for evaluating conformance robustness during geologic CO2 sequestration operations

Cited by 12 publications

References 45 publications

Improved geophysical monitoring of carbon sequestration through parameter linkage to reservoir modeling

Improved geophysical monitoring of carbon sequestration through parameter linkage to reservoir modeling

Geomechanical effects of co2 storage in geological structures: two case studies

CO2 plume evolution in a depleted natural gas reservoir: Modeling of conformance uncertainty reduction over time

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