Litcius/Paper detail

Modeling and scale-bridging using machine learning: nanoconfinement effects in porous media

Nicholas Lubbers, Animesh Agarwal, Yu Chen, Soyoun Son, Mohamed Mehana, Qinjun Kang, Satish Karra, Christoph Junghans, Timothy C. Germann, Hari Viswanathan

2020Scientific Reports48 citationsDOIOpen Access PDF

Abstract

Fine-scale models that represent first-principles physics are challenging to represent at larger scales of interest in many application areas. In nanoporous media such as tight-shale formations, where the typical pore size is less than 50 nm, confinement effects play a significant role in how fluids behave. At these scales, fluids are under confinement, affecting key properties such as density, viscosity, adsorption, etc. Pore-scale Lattice Boltzmann Methods (LBM) can simulate flow in complex pore structures relevant to predicting hydrocarbon production, but must be corrected to account for confinement effects. Molecular dynamics (MD) can model confinement effects but is computationally expensive in comparison. The hurdle to bridging MD with LBM is the computational expense of MD simulations needed to perform this correction. Here, we build a Machine Learning (ML) surrogate model that captures adsorption effects across a wide range of parameter space and bridges the MD and LBM scales using a relatively small number of MD calculations. The model computes upscaled adsorption parameters across varying density, temperature, and pore width. The ML model is 7 orders of magnitude faster than brute force MD. This workflow is agnostic to the physical system and could be generalized to further scale-bridging applications.

Topics & Concepts

NanoporousBridging (networking)Porous mediumLattice Boltzmann methodsStatistical physicsComputer scienceWorkflowParameter spaceScale (ratio)Length scaleMaterials sciencePorosityNanotechnologyMechanicsPhysicsMathematicsComputer networkStatisticsComposite materialQuantum mechanicsDatabaseLattice Boltzmann Simulation StudiesNanopore and Nanochannel Transport StudiesEnhanced Oil Recovery Techniques
Modeling and scale-bridging using machine learning: nanoconfinement effects in porous media | Litcius