Junyoung Hwang scite author profile

Clay minerals abound in sedimentary formations and the interaction of reservoir gases with their sub-micron features has direct relevance to many geo-energy applications. The quantification of gas uptake over a broad range of pressures is key towards assessing the significance of these physical interactions on enhancing storage capacity and gas recovery. We report a systematic investigation of the sorption properties of three source clay minerals-Na-rich montmorillonite (SWy-2), illite-smectite mixed layer (ISCz-1), and illite (IMt-2)-using CO 2 and CH 4 up to 30 MPa at 25 to 115 • C. The textural characterization of the clays by gas physisorption indicates that micropores are only partly accessible to N 2 (77 K) and Ar (87 K), while larger uptakes are measured with CO 2 (273 K) in the presence of illite. The supercritical excess sorption experiments confirm these findings, while revealing differences in uptake capacities that originate from the clay-specific pore size distribution. The Lattice Density Functional Theory (LDFT) model describes accurately the measured sorption isotherms by using a distribution of properly weighted slit pores and clay-specific solid-fluid interaction energies, which agree with isosteric heats of adsorption obtained experimentally. The model indicates that the maximum degree of pore occupancy is universal to the three 1 clays and the two gases, and it depends solely on temperature, reaching values near unity at the critical temperature. These observations greatly support the model's predictive capability for estimating gas adsorption on clay-bearing rocks and sediments.

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Measuring and modelling supercritical adsorption of CO2 and CH4 on montmorillonite source clay

Hwang

Joss

Pini

2019

Microporous and Mesoporous Materials

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A reference high-pressure CH4 adsorption isotherm for zeolite Y: results of an interlaboratory study

et al. 2020

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This paper reports the results of an international interlaboratory study led by the National Institute of Standards and Technology (NIST) on the measurement of high-pressure surface excess methane adsorption isotherms on NIST Reference Material RM 8850 (Zeolite Y), at 25 °C up to 7.5 MPa. Twenty laboratories participated in the study and contributed over one-hundred adsorption isotherms of methane on Zeolite Y. From these data, an empirical reference equation was determined, along with a 95% uncertainty interval (Uk=2). By requiring participants to replicate a high-pressure reference isotherm for carbon dioxide adsorption on NIST Reference Material RM 8852 (ZSM-5), this interlaboratory study also demonstrated the usefulness of reference isotherms in evaluating the performance of high-pressure adsorption experiments.

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Supercritical adsorption in micro- and meso-porous carbons and its utilisation for textural characterisation

Ansari

Joss

Hwang

et al. 2020

Microporous and Mesoporous Materials

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Understanding supercritical gas adsorption in porous carbons requires consistency between experimental measurements at representative conditions and theoretical adsorption models that correctly account for the solid's textural properties. We have measured unary CO 2 and CH 4 adsorption isotherms on a commercial mesoporous carbon up to 25 MPa at 40 • C, 60 • C and 80 • C. The experimental data are successfully described using a model based on the lattice Density Functional Theory (DFT) that has been newly developed for cylindrical pores and used alongside Ar (87K) physisorption to extract the representative pore sizes of the adsorbent. The agreement between model and experiments also includes important thermodynamic parameters, such as Henry constants and the isosteric heat of adsorption. The general applicability of our integrated workflow is validated by extending the analysis to a comprehensive literature data set on a microporous activated carbon. This comparison reveals the distinct pore-filling behaviour in micro-and mesopores at supercritical conditions, and highlights the limitations associated with using slit-pore models for the characterisation of porous carbons with significant amounts of mesoporosity. The lattice DFT represents a departure from simple adsorption models, such as the Langmuir equation, which cannot capture pore size dependent adsorption behaviour, and a practical alternative to molecular simulations, which are computationally expensive to implement.

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Chemo‐Mechanical Coupling in Fractured Shale With Water and Hydrocarbon Flow

Wenning

Madonna

Kurotori

et al. 2021

Geophysical Research Letters

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The transport of chemically reactive fluids through fractured clay‐rich rocks is fundamental to many subsurface engineering technologies. Here, we present results of direct‐shear laboratory experiments with simultaneous imaging by X‐ray Computed Tomography in Opalinus claystone with subsequent fluid injection to unravel the interplay between mechanical fracture deformation, fluid sorption, and flow. Under constant radial stress (σc = 1.5 MPa), the average mechanical aperture trued¯CT increases with shear displacement. Upon brine injection, trued¯CT is reduced by 40% relative to initial conditions (trued¯CT0=140−250 μm) and fluid‐sorption induces a divergent displacement of the two sample halves (Δh = ±50 − 170 μm) quantified by digital image correlation. None of these changes are observed in a control experiment with decane, indicating that creep is subordinate to swelling in sealing the fracture. Swelling‐induced changes in permeability within the fracture are heterogeneous and largely affect the fracture flow field, as computed using numerical simulations.

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Junyoung Hwang

Supercritical CO₂ and CH₄ Uptake by Illite-Smectite Clay Minerals

Measuring and modelling supercritical adsorption of CO2 and CH4 on montmorillonite source clay

A reference high-pressure CH4 adsorption isotherm for zeolite Y: results of an interlaboratory study

Supercritical adsorption in micro- and meso-porous carbons and its utilisation for textural characterisation

Chemo‐Mechanical Coupling in Fractured Shale With Water and Hydrocarbon Flow

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Junyoung Hwang

Supercritical CO2 and CH4 Uptake by Illite-Smectite Clay Minerals

Measuring and modelling supercritical adsorption of CO2 and CH4 on montmorillonite source clay

A reference high-pressure CH4 adsorption isotherm for zeolite Y: results of an interlaboratory study

Supercritical adsorption in micro- and meso-porous carbons and its utilisation for textural characterisation

Chemo‐Mechanical Coupling in Fractured Shale With Water and Hydrocarbon Flow

Contact Info

Product

Resources

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Supercritical CO₂ and CH₄ Uptake by Illite-Smectite Clay Minerals