Computed Tomography 3D Super-Resolution with Generative Adversarial Neural Networks: Implications on Unsaturated and Two-Phase Fluid Flow

Computed Tomography 3D Super-Resolution with Generative Adversarial Neural Networks: Implications on Unsaturated and Two-Phase Fluid Flow

Fluid flow characteristics are important to assess reservoir performance. Unfortunately, laboratory techniques are inadequate to know these characteristics, which is why numerical methods were developed. Such methods often use computed tomography (CT) scans as input but this technique is plagued by...

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Main Authors: Nick Janssens, Marijke Huysmans, Rudy Swennen
Format: Article
Language:English
Published: MDPI AG 2020-03-01
Series:Materials
Subjects:
super-resolution
x-ray computed tomography
relative permeability
unsaturated flow
lattice boltzmann method
Online Access:https://www.mdpi.com/1996-1944/13/6/1397
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spelling doaj-4b5f4021d57b44348498643fe2c944eb2020-11-25T02:32:09ZengMDPI AGMaterials1996-19442020-03-01136139710.3390/ma13061397ma13061397Computed Tomography 3D Super-Resolution with Generative Adversarial Neural Networks: Implications on Unsaturated and Two-Phase Fluid FlowNick Janssens0Marijke Huysmans1Rudy Swennen2Department of Earth- and Environmental Sciences, Katholieke Universiteit Leuven, Celestijnenlaan 200E, 3001 Leuven, BelgiumDepartment of Earth- and Environmental Sciences, Katholieke Universiteit Leuven, Celestijnenlaan 200E, 3001 Leuven, BelgiumDepartment of Earth- and Environmental Sciences, Katholieke Universiteit Leuven, Celestijnenlaan 200E, 3001 Leuven, BelgiumFluid flow characteristics are important to assess reservoir performance. Unfortunately, laboratory techniques are inadequate to know these characteristics, which is why numerical methods were developed. Such methods often use computed tomography (CT) scans as input but this technique is plagued by a resolution versus sample size trade-off. Therefore, a super-resolution method using generative adversarial neural networks (GANs) was used to artificially improve the resolution. Firstly, the influence of resolution on pore network properties and single-phase, unsaturated, and two-phase flow was analysed to verify that pores and pore throats become larger on average and surface area decreases with worsening resolution. These observations are reflected in increasingly overestimated single-phase permeability, less moisture uptake at lower capillary pressures, and high residual oil fraction after waterflooding. Therefore, the super-resolution GANs were developed which take low (12 µm) resolution input and increase the resolution to 4 µm, which is compared to the expected high-resolution output. These results better predicted pore network properties and fluid flow properties despite the overestimation of porosity. Relevant small pores and pore surfaces are better resolved thus providing better estimates of unsaturated and two-phase flow which can be heavily influenced by flow along pore boundaries and through smaller pores. This study presents the second case in which GANs were applied to a super-resolution problem on geological materials, but it is the first one to apply it directly on raw CT images and to determine the actual impact of a super-resolution method on fluid predictions.https://www.mdpi.com/1996-1944/13/6/1397super-resolutionx-ray computed tomographyrelative permeabilityunsaturated flowlattice boltzmann method
collection DOAJ
language English
format Article
sources DOAJ
author Nick Janssens
Marijke Huysmans
Rudy Swennen
spellingShingle Nick Janssens
Marijke Huysmans
Rudy Swennen
Computed Tomography 3D Super-Resolution with Generative Adversarial Neural Networks: Implications on Unsaturated and Two-Phase Fluid Flow
Materials
super-resolution
x-ray computed tomography
relative permeability
unsaturated flow
lattice boltzmann method
author_facet Nick Janssens
Marijke Huysmans
Rudy Swennen
author_sort Nick Janssens
title Computed Tomography 3D Super-Resolution with Generative Adversarial Neural Networks: Implications on Unsaturated and Two-Phase Fluid Flow
title_short Computed Tomography 3D Super-Resolution with Generative Adversarial Neural Networks: Implications on Unsaturated and Two-Phase Fluid Flow
title_full Computed Tomography 3D Super-Resolution with Generative Adversarial Neural Networks: Implications on Unsaturated and Two-Phase Fluid Flow
title_fullStr Computed Tomography 3D Super-Resolution with Generative Adversarial Neural Networks: Implications on Unsaturated and Two-Phase Fluid Flow
title_full_unstemmed Computed Tomography 3D Super-Resolution with Generative Adversarial Neural Networks: Implications on Unsaturated and Two-Phase Fluid Flow
title_sort computed tomography 3d super-resolution with generative adversarial neural networks: implications on unsaturated and two-phase fluid flow
publisher MDPI AG
series Materials
issn 1996-1944
publishDate 2020-03-01
description Fluid flow characteristics are important to assess reservoir performance. Unfortunately, laboratory techniques are inadequate to know these characteristics, which is why numerical methods were developed. Such methods often use computed tomography (CT) scans as input but this technique is plagued by a resolution versus sample size trade-off. Therefore, a super-resolution method using generative adversarial neural networks (GANs) was used to artificially improve the resolution. Firstly, the influence of resolution on pore network properties and single-phase, unsaturated, and two-phase flow was analysed to verify that pores and pore throats become larger on average and surface area decreases with worsening resolution. These observations are reflected in increasingly overestimated single-phase permeability, less moisture uptake at lower capillary pressures, and high residual oil fraction after waterflooding. Therefore, the super-resolution GANs were developed which take low (12 µm) resolution input and increase the resolution to 4 µm, which is compared to the expected high-resolution output. These results better predicted pore network properties and fluid flow properties despite the overestimation of porosity. Relevant small pores and pore surfaces are better resolved thus providing better estimates of unsaturated and two-phase flow which can be heavily influenced by flow along pore boundaries and through smaller pores. This study presents the second case in which GANs were applied to a super-resolution problem on geological materials, but it is the first one to apply it directly on raw CT images and to determine the actual impact of a super-resolution method on fluid predictions.
topic super-resolution
x-ray computed tomography
relative permeability
unsaturated flow
lattice boltzmann method
url https://www.mdpi.com/1996-1944/13/6/1397
work_keys_str_mv AT nickjanssens computedtomography3dsuperresolutionwithgenerativeadversarialneuralnetworksimplicationsonunsaturatedandtwophasefluidflow
AT marijkehuysmans computedtomography3dsuperresolutionwithgenerativeadversarialneuralnetworksimplicationsonunsaturatedandtwophasefluidflow
AT rudyswennen computedtomography3dsuperresolutionwithgenerativeadversarialneuralnetworksimplicationsonunsaturatedandtwophasefluidflow
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