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519 results on '"Bijeljic, Branko"'

1. Percolation without trapping: how Ostwald ripening during two-phase displacement in porous media alters capillary pressure and relative permeability

Author

Adebimpe, Ademola Isaac, Foroughi, Sajjad, Bijeljic, Branko, and Blunt, Martin J.

Subjects
Physics - Fluid Dynamics
Abstract

Conventional measurements of two-phase flow in porous media often use completely immiscible fluids, or are performed over time-scales of days to weeks. If applied to the study of gas storage and recovery, these measurements do not properly account for Ostwald ripening, significantly over-estimating the amount of trapping and hysteresis. When there is transport of dissolved species in the aqueous phase, local capillary equilibrium is achieved: this may take weeks to months on the centimetre-sized samples on which measurements are performed. However, in most subsurface applications where the two phases reside for many years, equilibrium can be achieved. We demonstrate that in this case, two-phase displacement in porous media needs to be modelled as percolation without trapping. A pore network model is used to quantify how to convert measurements made ignoring Ostwald ripening to correct trapped saturation, capillary pressure and relative permeability to account for this effect. We show that conventional measurements over-estimate the amount of capillary trapping by 20-25\%., Comment: 5 pages, 4 figures, 1 table

Published
2024

17. Multimodal Functions as Flow Signatures in Complex Porous Media

Author

Bijeljic, Branko, Raeini, Ali Q., Lin, Qingyang, and Blunt, Martin J.

Subjects
Physics - Fluid Dynamics
Abstract

This study refutes the premise that the distribution of flow speeds in complex porous media can be described by a simple function such as a normal or exponential variation. In many complex porous media, including those relevant for subsurface storage and recovery applications, a separation of scales exists between larger inter-granular pores and micro-porosity inside the grains, leading to different flow signatures that need to be described by multimodal functions with distinct flow field characteristics. We demonstrate this finding by devising a novel methodology to simulate fluid flow in carbonate rock based on a representation of the pore space obtained by differential X-ray imaging. The permeability assignment in the micro-porous space is estimated from the pore size inferred from mercury injection porosimetry. Model predictions considering micro-porosity agree well with experimentally measured porosities and permeabilities. The micro-porosity can contribute significantly to the overall permeability, particularly in the more heterogeneous media.

Published
2018

21. Generalized network modeling of capillary-dominated two-phase flow

Author

Raeini, Ali Q., Bijeljic, Branko, and Blunt, Martin J.

Subjects
Physics - Computational Physics, Physics - Fluid Dynamics
Abstract

We present a generalized network model for simulating capillary-dominated two-phase flow through porous media at the pore scale. Three-dimensional images of the pore space are discretized using a generalized network -- described in a companion paper (https://doi.org/10.1103/PhysRevE.96.013312) -- that comprises pores that are divided into smaller elements called half-throats and subsequently into corners. Half-throats define the connectivity of the network at the coarsest level, connecting each pore to half-throats of its neighboring pores from their narrower ends, while corners define the connectivity of pore crevices. The corners are discretized at different levels for accurate calculation of entry pressures, fluid volumes and flow conductivities that are obtained using direct simulation of flow on the underlying image. This paper discusses the two-phase flow model that is used to compute the averaged flow properties of the generalized network, including relative permeability and capillary pressure. We validate the model using direct finite-volume two-phase flow simulations on synthetic geometries, and then present a comparison of the model predictions with a conventional pore-network model and experimental measurements of relative permeability in the literature., Comment: This is a joint paper with another paper titled "Generalized network modeling: Network extraction as a coarse-scale discretization of the void space of porous media" (https://doi.org/10.1103/PhysRevE.96.013312). This manuscript is prepared for submission to Physical Review E as well

Published
2017
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22. Gradient Information Enhanced Image Segmentation and Automatic In Situ Contact Angle Measurement Applied to Images of Multiphase Flow in Porous Media.

Author

Gao, Yang, Foroughi, Sajjad, Ma, Zhuangzhuang, Yuan, Sanyi, Xiao, Lizhi, Bijeljic, Branko, and Blunt, Martin J.

Subjects
CONTACT angle, CONVOLUTIONAL neural networks, MULTIPHASE flow, IMAGE segmentation, POROUS materials
Abstract

A gradient‐information‐enhanced image segmentation method using convolutional neural networks is presented, and then combined with contact angle measurement to establish an automated processing workflow. For three‐dimensional X‐ray images, the segmentation accuracy at interfaces and sparsely distributed small objects directly influences the accuracy of the contact angle measurement. Leveraging reliable gradient information to train the neural network, this segmentation method addresses the issue of inaccurate segmentation of interfaces even at low resolution and with small objects present. Furthermore, memory requirements are reduced by performing analysis on orthogonal two‐dimensional planes. The workflow was tested on water‐wet Ketton limestone, as well as on both water‐wet and mixed‐wet sandstone and a reservoir carbonate. The results from both the segmentation and contact angle measurements underscore the effectiveness of the approach. Notably, the workflow shows considerable generalizability and robustness, even with varying wettability and lithology. Plain Language Summary: We use convolutional neural networks enhanced with gradient information to improve the accuracy of segmentation of three‐dimensional images of porous media and the fluids in the pore space, especially at interfaces and for small objects, even when the images have low resolution. We tested the method on several data sets including water‐wet Ketton limestone, both water‐wet and mixed‐wet Bentheimer sandstone, and a reservoir carbonate. The results demonstrated the effectiveness of our approach compared to traditional methods for segmentation. A particular challenge is the determination of contact angle ‐ the local wettability ‐ at the three‐phase contact loop between two fluid phases and the solid. We show that our new method leads to reliable estimates of the distribution of contact angle for the samples studied. This work allows for more accurate image analysis in multiphase flow in porous media with applications in carbon dioxide and hydrogen storage. Key Points: A gradient information enhanced segmentation method is presented to assist automatic contact angle measurementsThe gradient information method reduces the problems associated with low image resolution and manual segmentation [ABSTRACT FROM AUTHOR]

Published
2024
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25. InterPore Journal Goes Online

Author

Shokri, Nima, primary, Armstrong, Ryan T., additional, Bijeljic, Branko, additional, Van Genuchten, Martinus Th., additional, Helmig, Rainer, additional, Huber, Patrick, additional, Kjelstrup, Signe, additional, Or, Dani, additional, Shahidzadeh, Noushine, additional, Sun, Shuyu, additional, and Wildenschild, Dorthe, additional

Published
2024
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49. Incorporation of Sub‐Resolution Porosity Into Two‐Phase Flow Models With a Multiscale Pore Network for Complex Microporous Rocks.

Author

Foroughi, Sajjad, Bijeljic, Branko, Gao, Ying, and Blunt, Martin J.

Subjects
MULTISCALE modeling, POROSITY, SINGLE-phase flow, POROUS materials, MULTIPHASE flow, TWO-phase flow, CAPILLARY flow
Abstract

Porous materials, such as carbonate rocks, frequently have pore sizes which span many orders of magnitude. This is a challenge for models that rely on an image of the pore space, since much of the pore space may be unresolved. In this work, sub‐resolution porosity in X‐ray images is characterized using differential imaging which quantifies the difference between a dry scan and 30 wt% potassium iodide brine saturated images. Once characterized, we develop a robust workflow to incorporate the sub‐resolution pore space into a network model using Darcy‐type elements called microlinks. Each grain voxel with sub‐resolution porosity is assigned to the two nearest resolved pores using an automatic dilation algorithm. By including these microlinks with empirical models in flow modeling, we simulate single‐phase and multiphase flow. By fine‐tuning the microlink empirical models, we match permeability, formation factor (the ratio of the resistivity of a rock filled with brine to the resistivity of that brine), and drainage capillary pressure to experimental results. We then show that our model can successfully predict steady‐state relative permeability measurements on a water‐wet Estaillades carbonate sample within the uncertainty of the experiments and modeling. Our approach of incorporating sub‐resolution porosity in two‐phase flow modeling using image‐based multiscale pore network techniques can capture complex pore structures and accurately predict flow behavior in porous materials with a wide range of pore size. Key Points: A dilation‐based algorithm adds sub‐resolution porosity, quantified by differential imaging, as microlinks to an extracted pore networkEmpirical models are used to characterize the flow properties of microlinksThe tuned multiscale network, using permeability, formation factor, and capillary pressure, matches experimental relative permeability [ABSTRACT FROM AUTHOR]

Published
2024
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