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Prediction of effective diffusivity of porous media using deep learning method based on sample structure information self-amplification

H. Wang, Ying Yin, Xinyu Hui, Junqiang Bai, Zhiguo Qu

2020Energy and AI63 citationsDOIOpen Access PDF

Abstract

Effective diffusivity is one of the basic transport coefficients used to describe the mass transport capability of a porous medium. In this study, a deep learning method based on a convolutional neural network (CNN) with sample structure information self-amplification is proposed to predict the effective diffusivity of a porous medium, which is considerably influenced by the morphological and topological parameters of the porous medium. In this method, the geometric structures of three-dimensional (3D) porous media are reproduced via a stochastic reconstruction method. Datasets of the effective diffusivities of the reconstructed porous media were first established by the pore-scale lattice Boltzmann method (LBM) simulation. A large number of geometric structures of 3D porous media are obtained using the proposed sample structure information self-amplification approach. The 3D geometric structure information and corresponding effective diffusivities are directionally applied to a CNN for training and prediction. The effective diffusivities of media with porosities ranging from 0.48 to 0.58 are employed as training datasets, and the effective diffusivities of media with a broader porosity range of 0.39 to 0.79 are predicted by CNN. The CNN model can achieve a fast and accurate prediction of the effective diffusivity. The relative error between the CNN and LBM is 0.026%–8.95% with porosities ranging from 0.39 to 0.79. For a typical case with a porosity of 0.5, the computation time required by the CNN model is only 3 × 10−4 h, while the computation time for the same case is 16.96 h using the LBM. These findings indicate that the proposed deep learning method has a powerful learning ability; it is time-saving, provides accurate predictions, and can serve as a promising and powerful tool to predict the transport coefficients of complex porous media.

Topics & Concepts

Porous mediumThermal diffusivityComputationRangingConvolutional neural networkLattice Boltzmann methodsPorosityComputer scienceMaterials scienceApproximation errorArtificial intelligenceAlgorithmBiological systemPhysicsThermodynamicsComposite materialTelecommunicationsBiologyLattice Boltzmann Simulation StudiesHeat and Mass Transfer in Porous MediaNMR spectroscopy and applications
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