Impact of relative permeability hysteresis on geological CO<sub>2</sub> storage

Juanes, Rubén; Spiteri, Elizabeth; Orr, Franklin M.; Blunt, Martin J.

doi:10.1029/2005wr004806

Cited by 724 publications

(479 citation statements)

References 65 publications

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“…Trapping occurs primarily after injection, when the CO 2 migrates due to the aquifer slope and the natural head gradient. As the buoyant plume of mobile CO 2 (dark gray) rises and spreads away from the well array, residual trapping immobilizes blobs of CO 2 in its wake (light gray) (19,29,30), and solubility trapping shrinks the plume from below (blue) (20, 21).…”

Section: Storage Demand Vs Supply Dictates Ccs Lifetimementioning

confidence: 99%

“…Although trapping can be analyzed over a wide range of length scales, we consider trapping at the large scale of an entire geologic basin because large volumes of CO 2 will need to be stored to offset emissions (3). We consider residual trapping, in which blobs of CO 2 become immobilized by capillary forces (19), and solubility trapping, in which CO 2 dissolves into the groundwater (20,21), because these mechanisms operate over relatively short timescales and provide secure forms of storage ( Fig. 1 A and B).…”

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confidence: 99%

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Lifetime of carbon capture and storage as a climate-change mitigation technology

Szulczewski

MacMinn²,

Herzog³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

409

311

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In carbon capture and storage (CCS), CO 2 is captured at power plants and then injected underground into reservoirs like deep saline aquifers for long-term storage. While CCS may be critical for the continued use of fossil fuels in a carbon-constrained world, the deployment of CCS has been hindered by uncertainty in geologic storage capacities and sustainable injection rates, which has contributed to the absence of concerted government policy. Here, we clarify the potential of CCS to mitigate emissions in the United States by developing a storage-capacity supply curve that, unlike current large-scale capacity estimates, is derived from the fluid mechanics of CO 2 injection and trapping and incorporates injection-rate constraints. We show that storage supply is a dynamic quantity that grows with the duration of CCS, and we interpret the lifetime of CCS as the time for which the storage supply curve exceeds the storage demand curve from CO 2 production. We show that in the United States, if CO 2 production from power generation continues to rise at recent rates, then CCS can store enough CO 2 to stabilize emissions at current levels for at least 100 y. This result suggests that the large-scale implementation of CCS is a geologically viable climate-change mitigation option in the United States over the next century.carbon sequestration | pressure dissipation | residual trapping | solubility trapping C arbon dioxide is a well-documented greenhouse gas, and a growing body of evidence indicates that anthropogenic CO 2 emissions are a major contributor to climate change (1). One promising technology to mitigate CO 2 emissions is carbon capture and storage (CCS) (2-4). In the context of this study, CCS involves capturing CO 2 from the flue gas of power plants, compressing it into a supercritical fluid, and then injecting it into deep saline aquifers for long-term storage (4, 5). Compared with other mitigation technologies such as renewable energy, CCS is important because it may enable the continued use of fossil fuels, which currently supply >80% of the primary power for the planet (6, 7). We focus on CO 2 produced by power plants because electric power generation currently accounts for >40% of worldwide CO 2 emissions (8) and because power plants are large, stationary point sources of emissions where CO 2 capture technology will likely be deployed first (4). We further restrict our analysis to coal-and gas-fired power plants because they emit more CO 2 than any other type of plant: Since 2000, they have emitted ∼97% by mass of the total CO 2 produced by electricitygenerating power plants in the United States (9). We focus on storing this CO 2 in deep saline aquifers because they are geographically widespread and their storage capacity is potentially very large (4, 5).We define the storage capacity of a saline aquifer to be the maximum amount of CO 2 that could be injected and securely stored under geologic constraints, such as the aquifer's size and the integrity of its caprock. Regulatory, legal, and economic factors...

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Section: Storage Demand Vs Supply Dictates Ccs Lifetimementioning

confidence: 99%

mentioning

confidence: 99%

Lifetime of carbon capture and storage as a climate-change mitigation technology

Szulczewski

MacMinn²,

Herzog³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

409

311

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“…This is due to the following two facts: (1) contact angle hysteresis (the difference between ACA and RCA) influences the relative permeability, implying that factors affecting contact angle hysteresis such as pressure, and pore throat size should be considered to select the relative permeability in numerical simulation; and (2) the presence of trapped nonwetting phase (CO2) influences the flow path of wetting fluid (water). When trapped non-wetting phase (CO2) occupies larger pores, it causes the injected wetting fluid (water) to change its flow paths, resulting in decreased relative permeability [56]. Spiteri et al [57] have performed numerical modelling of a Water Alternating Gas (WAG) system for CO2 sequestration and shown favorable results for residual trapping due to relative permeability hysteresis by decreasing leakage risk through lowering the accumulation of CO2 plum under caprock.…”

Section: Contact Angle Hysteresismentioning

confidence: 99%

Direct Measurement of Static and Dynamic Contact Angles Using a Random Micromodel Considering Geological CO2 Sequestration

Jafari

Jung

2017

Sustainability

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Abstract:The pore-level two-phase fluids flow mechanism needs to be understood for geological CO 2 sequestration as a solution to mitigate anthropogenic emission of carbon dioxide. Capillary pressure at the interface of water-CO 2 influences CO 2 injectability, capacity, and safety of the storage system. Wettability usually measured by contact angle is always a major uncertainty source among important parameters affecting capillary pressure. The contact angle is mostly determined on a flat surface as a representative of the rock surface. However, a simple and precise method for determining in situ contact angle at pore-scale is needed to simulate fluids flow in porous media. Recent progresses in X-ray tomography technique has provided a robust way to measure in situ contact angle of rocks. However, slow imaging and complicated image processing make it impossible to measure dynamic contact angle. In the present paper, a series of static and dynamic contact angles as well as contact angles on flat surface were measured inside a micromodel with random pattern of channels under high pressure condition. Our results showed a wide range of pore-scale contact angles, implying complexity of the pore-scale contact angle even in a highly smooth and chemically homogenous glass micromodel. Receding contact angle (RCA) showed more reproducibility compared to advancing contact angle (ACA) and static contact angle (SCA) for repeating tests and during both drainage and imbibition. With decreasing pore size, RCA was increased. The hysteresis of the dynamic contact angle (ACA-RCA) was higher at pressure of one megapascal in comparison with that at eight megapascals. The CO 2 bubble had higher mobility at higher depths due to lower hysteresis which is unfavorable. CO 2 bubbles resting on the flat surface of the micromodel channel showed a wide range of contact angles. They were much higher than reported contact angle values observed with sessile drop or captive bubble tests on a flat plate of glass in previous reports. This implies that more precaution is required when estimating capillary pressure and leakage risk.

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“…We refer in this paper to the wetting phase as water and the non-wetting phase as oil, although the process is applicable to any pairs of immiscible fluids, including CO 2 -brine systems where large-scale trapping is extremely important for storage security (Saadatpoor et al 2010;Juanes et al 2006). …”

Section: Steady-state Upscalingmentioning

confidence: 99%

Large-scale Invasion Percolation with Trapping for Upscaling Capillary-Controlled Darcy-scale Flow

Nooruddin

Blunt

2017

Transp Porous Med

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We apply steady-state capillary-controlled upscaling in heterogeneous environments. A phase may fail to form a connected path across a given domain at capillary equilibrium. Moreover, even if a continuous saturation path exists, some regions of the domain may produce disconnected clusters that do not contribute to the overall connectivity of the system. In such cases, conventional upscaling processes might not be accurate since identification and removal of these isolated clusters are extremely important to the global connectivity of the system and the stability of the numerical solvers. In this study, we address the impact of percolation during capillary-controlled displacements in heterogeneous porous media and present a comprehensive investigation using random absolute permeability fields, for water-wet, oil-wet and mixed-wet systems, where J-function scaling is used to relate capillary pressure, porosity and absolute permeabilities in each grid cell. Important information is revealed about the average connectivity of the phases and trapping at the Darcy scale due to capillary forces. We show that in oil-wet and mixed-wet media, large-scale trapping of oil controlled by variations in local capillary pressure may be more significant than the local trapping, controlled by pore-scale displacement.

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Impact of relative permeability hysteresis on geological CO₂ storage

Cited by 724 publications

References 65 publications

Lifetime of carbon capture and storage as a climate-change mitigation technology

Lifetime of carbon capture and storage as a climate-change mitigation technology

Direct Measurement of Static and Dynamic Contact Angles Using a Random Micromodel Considering Geological CO2 Sequestration

Large-scale Invasion Percolation with Trapping for Upscaling Capillary-Controlled Darcy-scale Flow

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Impact of relative permeability hysteresis on geological CO2 storage

Cited by 724 publications

References 65 publications

Lifetime of carbon capture and storage as a climate-change mitigation technology

Lifetime of carbon capture and storage as a climate-change mitigation technology

Direct Measurement of Static and Dynamic Contact Angles Using a Random Micromodel Considering Geological CO2 Sequestration

Large-scale Invasion Percolation with Trapping for Upscaling Capillary-Controlled Darcy-scale Flow

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Impact of relative permeability hysteresis on geological CO₂ storage