Impact of pressure dissipation on fluid injection into layered aquifers

Jenkins, Luke; Foschi, Martino; MacMinn, Christopher W.

doi:10.1017/jfm.2019.593

Cited by 6 publications

(26 citation statements)

References 38 publications

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“…Our geological setting is the same as in Jenkins et al [25]. We consider a layered system comprising an alternating stack of N z aquifers and N z +1 seals (Figure 1).…”

Section: Theoretical Modelmentioning

confidence: 99%

“…In a confined layer, distributed leakage is complicated by the fact that both fluids can cross the seals at any point, leading to a rich flow problem that has not previously been explored. Jenkins et al [25] recently studied distributed leakage of the ambient fluid (brine) during gas injection into a layered system of horizontal aquifers separated by thin seals, but assuming that the gas cannot leak (i.e., that the entry pressure is never exceeded). Distributed brine leakage is interesting and important in its own right, because it enables strong vertical pressure dissipation and therefore plays an important role in mitigating pressure buildup during gas injection [26][27][28].…”

Section: Introductionmentioning

confidence: 99%

“…Distributed brine leakage is interesting and important in its own right, because it enables strong vertical pressure dissipation and therefore plays an important role in mitigating pressure buildup during gas injection [26][27][28]. Jenkins et al [25] showed that vertical pressure dissipation is also coupled to the motion of the gas plume, leading to a more compact plume shape by suppressing the formation of the advancing gas tongue.…”

Section: Introductionmentioning

confidence: 99%

“…A key aspect of the present study is that, as in Jenkins et al [25], we focus on a layered system. This enables a strong coupling between injection, migration, leakage, and pressure dissipation across layers.…”

Section: Introductionmentioning

confidence: 99%

“…We show here that this coupling becomes even more complex when gas leakage is introduced. In §II, we review the model of Jenkins et al [25] and extend it to include gas leakage. In §III, we outline our numerical scheme and then explore the different factors that control the buildup of capillary pressure along the underside of the seal.…”

Section: Introductionmentioning

confidence: 99%

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Gas injection and leakage in layered aquifers

Jenkins,

Foschi,

MacMinn

2019

Preprint

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Carbon dioxide (CO 2 ) injection into saline aquifers is one method of mitigating anthropogenic climate change. To ensure secure storage of this CO 2 , it is important to understand the interaction of CO 2 injection and migration with geological layering. For example, seismic monitoring at the Sleipner pilot project suggests that the injected CO 2 is ponding against, and leaking across, a series of thin, intermediate seals.Here, we develop a gravity-current model for weakly compressible, two-phase fluid migration in a system of layered aquifers. Our model includes vertical leakage of both water and gas across seals, where the latter is subject to a capillary entry threshold. We demonstrate that the buildup of capillary pressure is very sensitive to the conductivity and connectivity of water films in the gas region. We identify two associated limiting cases, where gas obstructs water flow either completely or not at all. We then explore the parameters that govern gas leakage and the resulting fluid distributions-demonstrating that this problem involves a complex interplay between pressure dissipation, capillary pressure buildup, and fluid migration. We show that decreasing the relative permeability of water in the gas region can initiate gas leakage or significantly increase the amount of gas leakage. Finally, we apply our model to rock properties expected for Sleipner and show that CO 2 injection may build up sufficient capillary pressure to invade the seals-suggesting that, contrary to conventional wisdom, CO 2 may be able to leak across the intermediate seals at Sleipner in the absence of a focused conduit.

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“…Our geological setting is the same as in Jenkins et al [25]. We consider a layered system comprising an alternating stack of N z aquifers and N z +1 seals (Figure 1).…”

Section: Theoretical Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Gas injection and leakage in layered aquifers

Jenkins,

Foschi,

MacMinn

2019

Preprint

Self Cite

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Evaluating CO ₂ retention risk of geological sequestration sites: physical, time-scale, and site style considerations

Davis,

Jonk,

Bohacs

2024

Geoenergy

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With some exceptions, such as fluid phase, pressure evolution, and reservoir geometry, evaluation of CO 2 retention for geological sequestration sites primarily involves well-established seal and trap concepts and methods developed by the petroleum industry. Inputs to a CO 2 retention evaluation (e.g., bed seal capacity analysis) include CO 2 phase, CO 2 and brine density, reservoir pressure and temperature, rock properties, and stress state. The inputs are used to perform capillary and mechanical seal analyses similar to the petroleum industry, but unlike hydrocarbons, CO 2 retention also occurs within the reservoir pore volume by capillary and solubility trapping, adding additional requirement for analyses using reservoir engineering concepts and methodology. Reservoir geometry types for CO 2 storage include conventional traps (depleted hydrocarbon fields, brine-filled traps) and brine-filled reservoirs that lack a conventional trap geometry (e.g., a monocline). Each geometry style and project phase (injection, near-term post-injection, long-term static) requires different retention considerations, for example the CO 2 plume extent and height. Based on a retention evaluation, retention risk and uncertainty may be articulated using a qualitative risk matrix that facilitates early screening, identification of data needs, possible mitigating strategies, and comparisons across a portfolio of potential sites. Thematic collection: This article is part of the Geoscience workflows for CO 2 storage collection available at: https://www.lyellcollection.org/topic/collections/geoscience-workflows-for-CO2-storage

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An integrated framework for surface deformation modelling and induced seismicity forecasting due to reservoir operations

Meyer

Smith

Bourne

et al. 2023

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Induced seismicity and surface deformation are common observable manifestations of the geomechanical effect of reservoir operations whether related to geothermal energy production, gas extraction, or the storage of carbon dioxyde, gas, air or hydrogen. Modeling tools to predict quantitatively surface deformation and seismicity based on operation data could thus help manage such reservoirs. To that effect, we present an integrated and modular modeling framework which combines reservoir modeling, geomechanical modeling and earthquake forecasting. To allow effective computational cost, we assume vertical flow equilibrium, semi-analytical Green functions to calculate surface deformation and poro-elastic stresses, and a simple earthquake nucleation model based on coulomb stress changes. We use the test case of the Groningen gas field in the Netherlands to validate the modeling framework and assess its usefulness for reservoir management. For this application, given the relative simplicity of this sandstone reservoir, we assume homogeneous porosity and permeability and single-phase flow. The model fits well the measured pressure, yielding a RMSE of 0.95 MPa, and the seismicity observations as well. The pressure residuals show however a systematic increase with time that probably reflects groundwater ingression into the depleted reservoir. The interaction with groundwater could be accounted for by implementing a multi-phase flow VFE model. This is probably the major factor that limits the general applicability of the modeling framework. The modeled subsidence and seismicity fits nonetheless very well the historical observations in the case of the Groningen gas field.

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Impact of pressure dissipation on fluid injection into layered aquifers

Cited by 6 publications

References 38 publications

Gas injection and leakage in layered aquifers

Gas injection and leakage in layered aquifers

Evaluating CO ₂ retention risk of geological sequestration sites: physical, time-scale, and site style considerations

An integrated framework for surface deformation modelling and induced seismicity forecasting due to reservoir operations

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Impact of pressure dissipation on fluid injection into layered aquifers

Cited by 6 publications

References 38 publications

Gas injection and leakage in layered aquifers

Gas injection and leakage in layered aquifers

Evaluating CO 2 retention risk of geological sequestration sites: physical, time-scale, and site style considerations

An integrated framework for surface deformation modelling and induced seismicity forecasting due to reservoir operations

Contact Info

Product

Resources

About

Evaluating CO ₂ retention risk of geological sequestration sites: physical, time-scale, and site style considerations