Experimental study on effects of geologic heterogeneity in enhancing dissolution trapping of supercritical CO<sub>2</sub>

Agartan, Elif; Trevisan, Luca; Cihan, Abdullah; Birkhölzer, Jens; Zhou, Quanlin; Illangasekare, Tissa H.

doi:10.1002/2014wr015778

Cited by 100 publications

(60 citation statements)

References 67 publications

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“…(7)). Fast mixing and spreading towards higher depths improve the long-term storage of dissolved CO 2 throughout the aquifer6, because CO 2 is likely to remain in aquifer due to residual and mineral trapping even if the pressure were to drop due to a failure of the cap rock.…”

Section: Resultsmentioning

confidence: 99%

“…Geological sequestration of carbon dioxide (CO 2 ) has been proposed as a technology to reduce the amount of CO 2 emitted into the atmosphere123456. The main processes controlling the trapping of CO 2 during geological sequestration are storage of supercritical CO 2 in a gas cap, CO 2 dissolution in brine, known as solubility trapping78, residual trapping due to hysteresis910, and mineral trapping by CO 2 precipitation as secondary carbonates11.…”

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confidence: 99%

“…These studies concluded that permeability heterogeneity could have a significant impact on the onset, rate, and characteristic behavior of density-driven flow of CO 2 . On the other hand, theoretical26, numerical27, and experimental6 results suggest that density-driven flow may not always lead to significant convective mixing especially in layered systems containing low-permeability zones; CO 2 may actually become immobilized in these zones. In order to quantify the effects of vertical heterogeneity, Green and Ennis-King28 developed a simple model consisting of a random and uncorrelated distribution of horizontal, impermeable barriers with a given overall volume fraction (0.04% and 0.15%).…”

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confidence: 99%

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Critical Dynamics of Gravito-Convective Mixing in Geological Carbon Sequestration

Soltanian

Amooie

Dai

et al. 2016

Sci Rep

100

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When CO2 is injected in saline aquifers, dissolution causes a local increase in brine density that can cause Rayleigh-Taylor-type gravitational instabilities. Depending on the Rayleigh number, density-driven flow may mix dissolved CO2 throughout the aquifer at fast advective time-scales through convective mixing. Heterogeneity can impact density-driven flow to different degrees. Zones with low effective vertical permeability may suppress fingering and reduce vertical spreading, while potentially increasing transverse mixing. In more complex heterogeneity, arising from the spatial organization of sedimentary facies, finger propagation is reduced in low permeability facies, but may be enhanced through more permeable facies. The connectivity of facies is critical in determining the large-scale transport of CO2-rich brine. We perform high-resolution finite element simulations of advection-diffusion transport of CO2 with a focus on facies-based bimodal heterogeneity. Permeability fields are generated by a Markov Chain approach, which represent facies architecture by commonly observed characteristics such as volume fractions. CO2 dissolution and phase behavior are modeled with the cubic-plus-association equation-of-state. Our results show that the organization of high-permeability facies and their connectivity control the dynamics of gravitationally unstable flow. We discover new flow regimes in both homogeneous and heterogeneous media and present quantitative scaling relations for their temporal evolution.

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Section: Resultsmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Critical Dynamics of Gravito-Convective Mixing in Geological Carbon Sequestration

Soltanian

Amooie

Dai

et al. 2016

Sci Rep

100

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“…Local scCO 2 dissolution may also affect enhanced dissolution by convection. So far, all studies of convection-enhanced dissolution have assumed the presence of a boundary layer of dsCO 2 at solubility at the top of study domain in numerical simulations (e.g., Ennis-King and Paterson, 2005;Riaz et al, 2006;Pau et al, 2010) or have introduced gaseous CO 2 or an analogue fluid into an aperture in 2D Hele-Shaw cells or packed sands or glass beads in 1D columns or 2D sand tanks (Kneafsey and Pruess, 2010;Agartan et al, 2015). The non-equilibrium dissolution may result in dsCO 2 concentration in the boundary layer that slowly increases with time before reaching solubility, leading to the non-instantaneous dissolution at certain spatial scales.…”

Section: Introductionmentioning

confidence: 99%

“…The non-equilibrium dissolution may result in dsCO 2 concentration in the boundary layer that slowly increases with time before reaching solubility, leading to the non-instantaneous dissolution at certain spatial scales. This slow process will affect the development of a stable, diffusion-dominant boundary layer of dsCO 2 -containing brine, the onset and initialization of unstable fingers of dsCO 2 originating from the boundary layer, and the evolution, merging, and decay of these fingers in both homogeneous and heterogeneous porous media (Ennis-King and Paterson, 2003;Kneafsey and Pruess, 2010;Neufeld et al, 2010;Backhaus et al, 2011;Aggelopoulos and Tsakiroglou, 2012;MacMinn et al, 2012;Agartan et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Pore-scale supercritical CO2 dissolution and mass transfer under drainage conditions

Chang

Zhou

Oostrom

et al. 2017

Advances in Water Resources

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Abstract:Recently, both core-and pore-scale imbibition experiments have shown nonequilibrium dissolution of supercritical CO 2 (scCO 2 ) and a prolonged depletion of residual scCO 2 . In this study, pore-scale scCO 2 dissolution and mass transfer under drainage conditions were investigated using a two-dimensional heterogeneous micromodel and a novel fluorescent water dye with a sensitive pH range between 3.7 and 6.5. Drainage experiments were conducted at 9 MPa and 40 °C by injecting scCO 2 into the sandstone-analogue pore network initially saturated by water without dissolved CO 2 (dsCO 2 ). During the experiments, time-lapse images of dye intensity, reflecting water pH, were obtained. These images show non-uniform pH in individual pores and pore clusters, with average pH levels gradually decreasing with time.Further analysis on selected pores and pore clusters shows that (1) rate-limited mass transfer prevails with slowly decreasing pH over time when the scCO 2 -water interface area is low with respect to the volume of water-filled pores and pore clusters, (2) fast scCO 2 dissolution and phase equilibrium occurs when scCO 2 bubbles invade into water-filled pores, significantly enhancing the area-to-volume ratio, and (3) a transition from rate-limited to diffusion-limited mass transfer occurs in a single pore when a medium area-to-volume ratio is prevalent. The analysis also shows that two fundamental processes -scCO 2 dissolution at phase interfaces and diffusion of dsCO 2 at the pore scale (10-100 µm), observed after scCO 2 bubble invasion into water-filled pores without pore throat constraints, are relatively fast. The overall slow dissolution of scCO 2 in the millimeter-scale micromodel can be attributed to the small area-to-volume ratios that represent pore-throat configurations and characteristics of phase interfaces. This finding is applicable for the behavior of dissolution at pore, core, and field scales when water-filled pores and pore clusters of varying size are surrounded by scCO 2 at narrow pore throats.

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On the choice of analogue fluids in CO₂ convective dissolution experiments

Raad

Emami-Meybodi

Hassanzadeh

2016

Water Resources Research

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Mixtures of ethylene glycol and methanol (EG‐MeOH) have been used as an analogue system (i.e., EG‐MeOH/water) in recent experiments in the context of convective dissolution of CO2 in deep saline aquifers. We have conducted a linear stability analysis of a gravitationally unstable diffusive boundary layer as well as direct numerical simulation of convective mixing involved in dissolution of EG‐MeOH species in water. We provide new evidences that EG‐MeOH does not resemble the dynamics of convective instabilities and subsequent mixing associated with dissolution of CO2 in water. It is found that there are fundamental differences in the evolution of the buoyancy‐driven instability and dynamics of convective mixing between CO2/water and a typical EG‐MeOH/water analogue system. Our results show that for a constant Rayleigh number, the onset of convective instabilities for EG‐MeOH/water can be different by an order of magnitude as compared with CO2/water. In addition, EG‐MeOH/water system reveals different dynamics associated with the convective mixing as compared to CO2/water system. This study improves our understanding of the instability behavior of analogue systems, their proper selection, and motivates further experiments.

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Experimental study on effects of geologic heterogeneity in enhancing dissolution trapping of supercritical CO₂

Cited by 100 publications

References 67 publications

Critical Dynamics of Gravito-Convective Mixing in Geological Carbon Sequestration

Critical Dynamics of Gravito-Convective Mixing in Geological Carbon Sequestration

Pore-scale supercritical CO2 dissolution and mass transfer under drainage conditions

On the choice of analogue fluids in CO₂ convective dissolution experiments

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Experimental study on effects of geologic heterogeneity in enhancing dissolution trapping of supercritical CO2

Cited by 100 publications

References 67 publications

Critical Dynamics of Gravito-Convective Mixing in Geological Carbon Sequestration

Critical Dynamics of Gravito-Convective Mixing in Geological Carbon Sequestration

Pore-scale supercritical CO2 dissolution and mass transfer under drainage conditions

On the choice of analogue fluids in CO2 convective dissolution experiments

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Experimental study on effects of geologic heterogeneity in enhancing dissolution trapping of supercritical CO₂

On the choice of analogue fluids in CO₂ convective dissolution experiments