A gradient-based deep neural network model for simulating multiphase flow in porous media

Yan, Bicheng; Harp, Dylan Robert; Chen, Bailian; Hoteit, Hussein; Pawar, Rajesh J.

doi:10.1016/j.jcp.2022.111277

Title: A gradient-based deep neural network model for simulating multiphase flow in porous media

Journal Article · Tue May 10 00:00:00 EDT 2022 · Journal of Computational Physics

DOI:https://doi.org/10.1016/j.jcp.2022.111277· OSTI ID:1894836

^[1];

^[2]; Chen, Bailian ^[2]; Hoteit, Hussein ^[1];

^[2]

King Abdullah University of Science and Technology (KAUST), Thuwal (Saudi Arabia)
Los Alamos National Laboratory (LANL), Los Alamos, NM (United States)

We report simulation of multiphase flow in porous media is crucial for the effective management of subsurface energy and environment-related activities. The numerical simulators used for modeling such processes rely on spatial and temporal discretization of the governing mass and energy balance partial-differential equations (PDEs) into algebraic systems via finite-difference/volume/element methods. These simulators usually require dedicated software development and maintenance, and suffer low efficiency from a runtime and memory standpoint for problems with multi-scale heterogeneity, coupled-physics processes or fluids with complex phase behavior. Therefore, developing cost-effective, data-driven models can become a practical choice, and in this work, we choose deep learning approaches as they can handle high dimensional data and accurately predict state variables with strong nonlinearity. In this paper, we describe a gradient-based deep neural network (GDNN) constrained by the physics related to multiphase flow in porous media. We tackle the nonlinearity of flow in porous media induced by rock heterogeneity, fluid properties, and fluid-rock interactions by decomposing the nonlinear PDEs into a dictionary of elementary differential operators. We use a combination of operators to handle rock spatial heterogeneity and fluid flow by advection. Since the augmented differential operators are inherently related to the physics of fluid flow, we treat them as first principles prior knowledge to regularize the GDNN training. We use the example of pressure management at geologic CO₂ storage sites, where CO₂ is injected in saline aquifers and brine is produced, and apply GDNN to construct a predictive model that is trained with physics-based simulation data and emulates the physics process. We demonstrate that GDNN can effectively predict the nonlinear patterns of subsurface responses, including the temporal and spatial evolution of the pressure and saturation plumes. We also successfully extend the GDNN to convolutional neural network (CNN), namely gradient-based CNN (GCNN), and validate its capability to improve the prediction accuracy. GDNN has great potential to tackle challenging problems that are governed by highly nonlinear physics and enable the development of data-driven models with higher fidelity.

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Research Organization:: Los Alamos National Laboratory (LANL), Los Alamos, NM (United States)

Sponsoring Organization:: USDOE Office of Fossil Energy (FE); King Abdullah University of Science and Technology (KAUST)

Grant/Contract Number:: 89233218CNA000001; BAS/1/1423-01-01

OSTI ID:: 1894836

Report Number(s):: LA-UR-21-21102; TRN: US2310439

Journal Information:: Journal of Computational Physics, Vol. 463; ISSN 0021-9991

Publisher:: ElsevierCopyright Statement

Country of Publication:: United States

Language:: English

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