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A hybrid machine-learning approach for analysis of methane hydrate formation dynamics in porous media with synchrotron CT imaging

Fast multi-phase processes in methane hydrate bearing samples pose a challenge for quantitative micro-computed tomography study and experiment steering due to complex tomographic data analysis involving time-consuming segmentation procedures. This is because of the sample’s multi-scale structure, wh...

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Autores principales: Fokin, Mikhail I., Nikitin, Viktor V., Duchkov, Anton A.
Formato: Online Artículo Texto
Lenguaje:English
Publicado: International Union of Crystallography 2023
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10481264/
https://www.ncbi.nlm.nih.gov/pubmed/37466970
http://dx.doi.org/10.1107/S1600577523005635
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author Fokin, Mikhail I.
Nikitin, Viktor V.
Duchkov, Anton A.
author_facet Fokin, Mikhail I.
Nikitin, Viktor V.
Duchkov, Anton A.
author_sort Fokin, Mikhail I.
collection PubMed
description Fast multi-phase processes in methane hydrate bearing samples pose a challenge for quantitative micro-computed tomography study and experiment steering due to complex tomographic data analysis involving time-consuming segmentation procedures. This is because of the sample’s multi-scale structure, which changes over time, low contrast between solid and fluid materials, and the large amount of data acquired during dynamic processes. Here, a hybrid approach is proposed for the automatic segmentation of tomographic data from time-resolved imaging of methane gas-hydrate formation in sandy granular media, which includes a deep-learning 3D U-Net model. To prepare a training dataset for the 3D U-Net, a technique to automate data labeling based on sample-specific information about the mineral matrix immobility and occasional fluid movement in pores is proposed. Automatic segmentation allowed for studying properties of the hydrate growth in pores, as well as dynamic processes such as incremental flow and redistribution of pore brine. Results of the quantitative analysis showed that for typical gas-hydrate stability parameters (100 bar methane pressure, 7°C temperature) the rate of formation is slow (less than 1% per hour), after which the surface area of contact between brine and gas increases, resulting in faster formation (2.5% per hour). Hydrate growth reaches the saturation point after 11 h of the experiment. Finally, the efficacy of the proposed segmentation scheme in on-the-fly automatic data analysis and experiment steering with zooming to regions of interest is demonstrated.
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spelling pubmed-104812642023-09-07 A hybrid machine-learning approach for analysis of methane hydrate formation dynamics in porous media with synchrotron CT imaging Fokin, Mikhail I. Nikitin, Viktor V. Duchkov, Anton A. J Synchrotron Radiat Research Papers Fast multi-phase processes in methane hydrate bearing samples pose a challenge for quantitative micro-computed tomography study and experiment steering due to complex tomographic data analysis involving time-consuming segmentation procedures. This is because of the sample’s multi-scale structure, which changes over time, low contrast between solid and fluid materials, and the large amount of data acquired during dynamic processes. Here, a hybrid approach is proposed for the automatic segmentation of tomographic data from time-resolved imaging of methane gas-hydrate formation in sandy granular media, which includes a deep-learning 3D U-Net model. To prepare a training dataset for the 3D U-Net, a technique to automate data labeling based on sample-specific information about the mineral matrix immobility and occasional fluid movement in pores is proposed. Automatic segmentation allowed for studying properties of the hydrate growth in pores, as well as dynamic processes such as incremental flow and redistribution of pore brine. Results of the quantitative analysis showed that for typical gas-hydrate stability parameters (100 bar methane pressure, 7°C temperature) the rate of formation is slow (less than 1% per hour), after which the surface area of contact between brine and gas increases, resulting in faster formation (2.5% per hour). Hydrate growth reaches the saturation point after 11 h of the experiment. Finally, the efficacy of the proposed segmentation scheme in on-the-fly automatic data analysis and experiment steering with zooming to regions of interest is demonstrated. International Union of Crystallography 2023-07-19 /pmc/articles/PMC10481264/ /pubmed/37466970 http://dx.doi.org/10.1107/S1600577523005635 Text en © Mikhail I. Fokin et al. 2023 https://creativecommons.org/licenses/by/4.0/This is an open-access article distributed under the terms of the Creative Commons Attribution (CC-BY) Licence, which permits unrestricted use, distribution, and reproduction in any medium, provided the original authors and source are cited.
spellingShingle Research Papers
Fokin, Mikhail I.
Nikitin, Viktor V.
Duchkov, Anton A.
A hybrid machine-learning approach for analysis of methane hydrate formation dynamics in porous media with synchrotron CT imaging
title A hybrid machine-learning approach for analysis of methane hydrate formation dynamics in porous media with synchrotron CT imaging
title_full A hybrid machine-learning approach for analysis of methane hydrate formation dynamics in porous media with synchrotron CT imaging
title_fullStr A hybrid machine-learning approach for analysis of methane hydrate formation dynamics in porous media with synchrotron CT imaging
title_full_unstemmed A hybrid machine-learning approach for analysis of methane hydrate formation dynamics in porous media with synchrotron CT imaging
title_short A hybrid machine-learning approach for analysis of methane hydrate formation dynamics in porous media with synchrotron CT imaging
title_sort hybrid machine-learning approach for analysis of methane hydrate formation dynamics in porous media with synchrotron ct imaging
topic Research Papers
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10481264/
https://www.ncbi.nlm.nih.gov/pubmed/37466970
http://dx.doi.org/10.1107/S1600577523005635
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