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Autori principali: Lee, Jonathan E., Zhu, Min, Xi, Ziqiao, Wang, Kun, Yuan, Yanhua O., Lu, Lu
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2409.16572
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author Lee, Jonathan E.
Zhu, Min
Xi, Ziqiao
Wang, Kun
Yuan, Yanhua O.
Lu, Lu
author_facet Lee, Jonathan E.
Zhu, Min
Xi, Ziqiao
Wang, Kun
Yuan, Yanhua O.
Lu, Lu
contents Geological carbon sequestration (GCS) involves injecting CO$_2$ into subsurface geological formations for permanent storage. Numerical simulations could guide decisions in GCS projects by predicting CO$_2$ migration pathways and the pressure distribution in storage formation. However, these simulations are often computationally expensive due to highly coupled physics and large spatial-temporal simulation domains. Surrogate modeling with data-driven machine learning has become a promising alternative to accelerate physics-based simulations. Among these, the Fourier neural operator (FNO) has been applied to three-dimensional synthetic subsurface models. Here, to further improve performance, we have developed a nested Fourier-DeepONet by combining the expressiveness of the FNO with the modularity of a deep operator network (DeepONet). This new framework is twice as efficient as a nested FNO for training and has at least 80% lower GPU memory requirement due to its flexibility to treat temporal coordinates separately. These performance improvements are achieved without compromising prediction accuracy. In addition, the generalization and extrapolation ability of nested Fourier-DeepONet beyond the training range has been thoroughly evaluated. Nested Fourier-DeepONet outperformed the nested FNO for extrapolation in time with more than 50% reduced error. It also exhibited good extrapolation accuracy beyond the training range in terms of reservoir properties, number of wells, and injection rate.
format Preprint
id arxiv_https___arxiv_org_abs_2409_16572
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Efficient and generalizable nested Fourier-DeepONet for three-dimensional geological carbon sequestration
Lee, Jonathan E.
Zhu, Min
Xi, Ziqiao
Wang, Kun
Yuan, Yanhua O.
Lu, Lu
Machine Learning
Computational Physics
Geological carbon sequestration (GCS) involves injecting CO$_2$ into subsurface geological formations for permanent storage. Numerical simulations could guide decisions in GCS projects by predicting CO$_2$ migration pathways and the pressure distribution in storage formation. However, these simulations are often computationally expensive due to highly coupled physics and large spatial-temporal simulation domains. Surrogate modeling with data-driven machine learning has become a promising alternative to accelerate physics-based simulations. Among these, the Fourier neural operator (FNO) has been applied to three-dimensional synthetic subsurface models. Here, to further improve performance, we have developed a nested Fourier-DeepONet by combining the expressiveness of the FNO with the modularity of a deep operator network (DeepONet). This new framework is twice as efficient as a nested FNO for training and has at least 80% lower GPU memory requirement due to its flexibility to treat temporal coordinates separately. These performance improvements are achieved without compromising prediction accuracy. In addition, the generalization and extrapolation ability of nested Fourier-DeepONet beyond the training range has been thoroughly evaluated. Nested Fourier-DeepONet outperformed the nested FNO for extrapolation in time with more than 50% reduced error. It also exhibited good extrapolation accuracy beyond the training range in terms of reservoir properties, number of wells, and injection rate.
title Efficient and generalizable nested Fourier-DeepONet for three-dimensional geological carbon sequestration
topic Machine Learning
Computational Physics
url https://arxiv.org/abs/2409.16572