Speaker
Description
Unintentional industrial releases of light non-aqueous phase liquids (LNAPLs) have led to contamination of soils and aquifers, posing serious risks to ecological sustainability and public health. Conventional remediation techniques, such as pump-and-treat systems, are commonly applied to address this problem. However, they often exhibit limited efficiency, as substantial fractions of residual hydrocarbons remain trapped within the pore space due to capillary forces and subsurface heterogeneity. These limitations highlight the need for alternative remediation strategies to improve LNAPL displacement efficiency in porous media. In this context, the use of viscous, shear-thinning fluids during in situ remediation has emerged as a promising approach, as their non-Newtonian behavior enables improved mobility control, a more uniform sweep, and enhanced hydrocarbon mobilization.
This study investigates the potential of unconventional in-situ flushing using complex shear-thinning fluids, with a particular focus on colloidal gas aphrons (CGA), to enhance LNAPL recovery. CGA fluids are gas-in-liquid dispersions stabilized by a polymer–surfactant system and exhibit non-Newtonian shear-thinning rheology, characterized by elevated apparent viscosity at low shear rates. In this work, the CGA formulation was prepared using biopolymer xanthan gum (XG) as the viscosifying agent and sodium dodecyl sulfate (SDS) as the surfactant, yielding a stable fluid with favorable rheological properties for controlled injection and transport in porous media. The performance of CGA-based flushing was investigated through laboratory-scale one-dimensional (1D) sand-packed column experiments, supported by numerical modeling.
1D column experiments demonstrated high diesel recovery using CGA injection, reaching approximately 98%. The CGA formulation exhibited stable flow behavior, characterized by piston-like displacement throughout the injection period. A numerical model was developed using Computer Modelling Group (CMG) STARS and calibrated against experimental observations, including sand-pack geometry, porosity, permeability, fluid properties, and injection conditions, with explicit incorporation of the shear-thinning behavior of the CGA.
The results demonstrate that the numerical model successfully reproduces the experimentally observed stable displacement front and LNAPL recovery, with predicted recovery deviating from experimental values by less than 1%. These discrepancies are mainly associated with simplified assumptions regarding pore-scale heterogeneity and CGA rheology. Based on this validation, the model was extended to two-dimensional (2D) simulations to investigate the influence of flow geometry on the local apparent viscosity of the shear-thinning CGA. These simulations revealed spatial variations in apparent viscosity and flow structure that cannot be captured by one-dimensional models. Overall, the combined experimental–numerical framework provides a robust basis for evaluating CGA-based flushing strategies. Future work will extend this approach to three-dimensional (3D) heterogeneous systems and near-field conditions, with particular emphasis on optimizing injection strategies, CGA slug design, and breakthrough control for sustainable LNAPL remediation.
| Country | France |
|---|---|
| Green Housing & Porous Media Focused Abstracts | This abstract is related to Green Housing |
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