Dynamics of snap-off and pore-filling events during two-phase fluid flow in permeable media

Singh, Kamaljit; Menke, Hannah P.; Andrew, Matthew; Lin, Qingyang; Rau, Christoph; Bijeljic, Branko

doi:10.1038/s41598-017-05204-4

Cited by 181 publications

(169 citation statements)

References 42 publications

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“…Therefore, the individual particle velocities can be determined based on the individual particle displacements over the given time interval. Both PIV and PTV usually use fluorescent tracer particles and a high‐resolution microscope (such as a confocal laser scanning microscope) to visualize the particle motion; for 3D imaging, it is important to match the refractive index between the fluids and particles. The flow velocity field obtained using μ‐PIV from 2D silicon‐based micromodel with an array of pillars by deep reactive ion etching and 3D glass bead‐packed micromodels is shown in Figure .…”

Section: Experiments and Resultsmentioning

confidence: 99%

Microfluidic Model Porous Media: Fabrication and Applications

Anbari

Chien

Datta

et al. 2018

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Complex fluid flow in porous media is ubiquitous in many natural and industrial processes. Direct visualization of the fluid structure and flow dynamics is critical for understanding and eventually manipulating these processes. However, the opacity of realistic porous media makes such visualization very challenging. Micromodels, microfluidic model porous media systems, have been developed to address this challenge. They provide a transparent interconnected porous network that enables the optical visualization of the complex fluid flow occurring inside at the pore scale. In this Review, the materials and fabrication methods to make micromodels, the main research activities that are conducted with micromodels and their applications in petroleum, geologic, and environmental engineering, as well as in the food and wood industries, are discussed. The potential applications of micromodels in other areas are also discussed and the key issues that should be addressed in the near future are proposed.

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Section: Experiments and Resultsmentioning

confidence: 99%

Microfluidic Model Porous Media: Fabrication and Applications

Anbari

Chien

Datta

et al. 2018

Small

171

158

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“…In capillary or residual trapping, CO 2 bubbles are entrapped inside rock pores by three mechanisms: (1) snap-off, (2) dead-end, and (3) by-passing. In snap-off, when water is invaded into a water-wet media, the water in the corner of a throat will swell gradually until it disconnects the non-wetting phase in the throat and forcibly pushes non-wetting into pore bodies [60,61]. The snap-off trapping mechanism is dominant for water-wet rocks with a high aspect ratio of pore-body diameter to pore-throat diameter [62].…”

Section: Comparing Contact Angle Of Bubbles On Flat Surface With Contmentioning

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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“…As an example, the width of the most external liquid bridge along a film is plotted as a function of time in figure 10: it decreases continuously with time until the break-up suddenly occurs, between t = 25 and t = 26 s. Studying in detail the dynamics of the non-local fluid redistribution within the liquid cluster following a pore invasion or of the liquid bridge break-up is not within the scope of the present study. Such topics have been considered in recent studies, using micromodels (Armstrong & Berg 2013) or packing of beads (Singh et al 2017a). On figure 8(b), the solid line shows the evolution of the liquid film ends as a function of the main menisci locations, averaged over the 28 spirals of the micromodel (so 28 liquid film-main meniscus pairs).…”

Section: Phase Distribution and Evaporation Rate As A Function Of Timementioning

confidence: 99%

Evaporation with the formation of chains of liquid bridges

et al. 2018

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OATAO is an open access repository that collects the work of Toulouse researchers and makes it freely available over the web where possible. This is an author-deposited version published in : http://oatao. The objective of the present work is to study the drying of a quasi-two-dimensional model porous medium, hereafter called the micromodel, initially filled w ith a pure liquid. The micromodel consists of cylinders measuring 50 µm in both height and diameter, radially arranged as a set of neighbouring spirals and sandwiched between two horizontal flat p lates. A s d rying p roceeds, a ir i nvades t he p ore space and elongated liquid films t rapped b y c apillary f orces f orm a long t he s pirals. These films c onsist o f ' chains' o f l iquid b ridges c onnecting n eighbouring c ylinders. They provide hydraulic connectivity between the central bulk liquid cluster and the external rim of the cylinder pattern, where evaporation takes place during a first constant-evaporation-rate drying stage. The first g oal o f t he p resent p aper i s to describe experimentally the phase distribution during drying, notably the evolution of liquid films, w hich c ontrols t he e vaporation k inetics ( e.g. t he d epinning o f t he films from the external rim signals the end of the constant-evaporation-rate period). Then, a viscocapillary model for the drying process is presented. It is based on numerical simulations of a liquid film c apillary s hape a nd v iscous fl ow wi thin a fil m. The model shows a reasonably good agreement with the experimental data. Thus, the present study is a step towards direct modelling of the effect of films o n t he drying of more complex porous media (e.g. packing of beads) and should be of interest for multiphase flow a pplications i n p orous m edia, i nvolving t ransport w ithin l iquid films.

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Dynamics of snap-off and pore-filling events during two-phase fluid flow in permeable media

Cited by 181 publications

References 42 publications

Microfluidic Model Porous Media: Fabrication and Applications

Microfluidic Model Porous Media: Fabrication and Applications

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

Evaporation with the formation of chains of liquid bridges

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