Direct characterization of solute transport in unsaturated porous media using fast X-ray synchrotron microtomography

Hasan, Sharul; Niasar, Vahid; Karadimitriou, Nikolaos; Godinho, José R. A.; Vo, Nghia T.; An, Senyou; Rabbani, Arash; Steeb, Holger

doi:10.1073/pnas.2011716117

Cited by 72 publications

(63 citation statements)

References 55 publications

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“…Additionally, as seen in Fig. 3, there is a positive power law relation between the dispersion coefficient and pore velocity as reported in the literature (Babaei and Joekar-Niasar 2016;An et al 2020;Bijeljic et al 2006;Hasan et al 2020). It should be noted that the precise nature of this power law dependence is at least partly a consequence of fitting the data with solution of the ADE, which assumes that the dispersive transport at the investigated experimental spatial and temporal scales is Fickian (Berkowitz et al 2006(Berkowitz et al , 2009.…”

Section: Homogeneous Modelsupporting

confidence: 83%

“…The ratio of advection to diffusion is referred to as the dimensionless Péclet number, P e = vL D m , where L denotes the characteristic transport length and D m is the molecular diffusion coefficient. The pore scale Péclet number is defined based on the characteristic diameter of a pore (Hasan et al 2019(Hasan et al , 2020, while the field Péclet number is usually defined based on the distance between the injection point and the measurement location; as such the values of these two Péclet numbers are significantly different. In addition, due to the presence of the no-slip boundary on solid surfaces, tortuosity of the porous material and preferential pathways, a solute will also spread along the flow direction via fluctuations from the average velocity.…”

Section: Introductionmentioning

confidence: 99%

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Process-Dependent Solute Transport in Porous Media

et al. 2021

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Solute transport under single-phase flow conditions in porous micromodels was studied using high-resolution optical imaging. Experiments examined loading (injection of ink-water solution into a clear water-filled micromodel) and unloading (injection of clear water into an ink-water filled micromodel). Statistically homogeneous and fine-coarse porous micromodels patterns were used. It is shown that the transport time scale during unloading is larger than that under loading, even in a micromodel with a homogeneous structure, so that larger values of the dispersion coefficient were obtained for transport during unloading. The difference between the dispersion values for unloading and loading cases decreased with an increase in the flow rate. This implies that diffusion is the key factor controlling the degree of difference between loading and unloading transport time scales, in the cases considered here. Moreover, the patterned heterogeneity micromodel, containing distinct sections of fine and coarse porous media, increased the difference between the transport time scales during loading and unloading processes. These results raise the question of whether this discrepancy in transport time scales for the same hydrodynamic conditions is observable at larger length and time scales.

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Section: Homogeneous Modelsupporting

confidence: 83%

Section: Introductionmentioning

confidence: 99%

Process-Dependent Solute Transport in Porous Media

et al. 2021

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“…A further problem with traditional approaches is that preferential flow fundamentally involves nonequilibrium processes, in that rapid flow through preferential pathways begins and usually ends long before there has been adequate time for equilibrium to be established in directions perpendicular to the direction of flow (Jarvis, 2007;Jarvis et al, 2016). Various studies, for example by Hasan et al (2020), have demonstrated this characteristic. Thus the process is not a diffusive one in which the state of water in each individual pore is determined by conditions in the adjacent pores.…”

Section: Theory and Modelsmentioning

confidence: 99%

Rapid-Response Unsaturated Zone Hydrology: Small-Scale Data, Small-Scale Theory, Big Problems

et al. 2021

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The unsaturated zone (UZ) extends across the Earth’s terrestrial surface and is central to many problems related to land and water resource management. Flow of water through the UZ is typically thought to be slow and diffusive, such that it could attenuate fluxes and dampen variability between atmospheric inputs and underlying aquifer systems. This would reduce water resource vulnerability to contaminants and water-related hazards. Reducing or negating that effect, however, spatially concentrated and rapid flow and transport through the unsaturated zone is surprisingly common and becoming more so with the increasing frequency and magnitude of extreme hydroclimatic events. Arising from the wide range in the rates and complex modes of nonlinear flow processes, these effects are among the most poorly characterized hydrologic phenomena. Issues of scale present additional difficulties. Equations representing unsaturated processes have been developed and tested on the basis of field and laboratory measurements typically made at scales from pore size to plot size. In contrast, related problems of significant interest to society, including floods, aquifer recharge, landslides, and groundwater contamination, range from watershed to regional scales. The disparity between the scale of our understanding and the scale of interest for societal problems has spurred application of these model equations at increasingly coarse resolutions over larger areas than can be justified by existing measurements or theory. This mismatch in scales requires an assumption that spatially averaging slow diffusive flow and rapid preferential flow can effectively represent the influence of both processes across vast areas. Given the currently inadequate recognition and quantitative characterization of focused and rapid processes in unsaturated flow, these phenomena are critically in need of expanded attention and effort.

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“…Following Although the optical/micromodel experimental studies provide valuable insights, the results might be only valid for 2-D systems as the percolation threshold and relative permeability curves are significantly different for 2-D versus 3-D systems (Sahimi, 1994). However, accurate characterization of dynamic two-phase flow in 3-D microscale experiments is very challenging (Armstrong et al, 2016;Hasan et al, 2020;Primkulov et al, 2019), especially under high flow rate conditions. To realize the rapid scanning, unconsolidated packed glass beads are recently utilized to analyze the flow patterns in the crossover zone (Hu et al, 2020;Patmonoaji et al, 2020).…”

Section: Immiscible Two-phase Flow Invasion Patternmentioning

confidence: 99%

Transition From Viscous Fingering to Capillary Fingering: Application of GPU‐Based Fully Implicit Dynamic Pore Network Modeling

Erfani

Godinez-Brizuela

et al. 2020

Water Resources Research

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Immiscible two-phase flow through porous materials exhibits different invasion patterns controlled by dynamic conditions, competition between the viscous and capillary forces, and the contrast between the fluids viscosities. Two distinct invasion patterns are viscous and capillary fingering. While the first one happens under unfavorable viscosity ratios at high injection rates, the second one happens when the viscous forces are very small compared to the capillary forces. Depending on whether the invasion is under the capillary fingering or viscous fingering regime, the remaining oil saturation and the effective permeability of the fluids can significantly change. The contribution of the present work has two key aspects: (a) It addresses how the remaining saturation changes at different flow rates (i.e., capillary numbers) for different unfavorable viscosity ratios in a three-dimensional system; (b) it presents a new dynamic pore network model using the fully implicit scheme which has been enhanced by the graphic processing unit (GPU) parallel computing. Additionally, the model has been carefully validated against micromodel experiments in both time and space, which to our best knowledge has not been reported in such detail in the literature. The results of the validated 3-D dynamic pore network model demonstrate the remaining saturation at the breakthrough time as a nonmonotonic trend with the imposed capillary number.

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Direct characterization of solute transport in unsaturated porous media using fast X-ray synchrotron microtomography

Cited by 72 publications

References 55 publications

Process-Dependent Solute Transport in Porous Media

Process-Dependent Solute Transport in Porous Media

Rapid-Response Unsaturated Zone Hydrology: Small-Scale Data, Small-Scale Theory, Big Problems

Transition From Viscous Fingering to Capillary Fingering: Application of GPU‐Based Fully Implicit Dynamic Pore Network Modeling

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