A DSMC-CFD coupling method using surrogate modelling for low-speed rarefied gas flows

Giorgos Tatsios*, Arun Chinnappan, Arshad Kamal, Nikos Vasileiadis, Stephanie Y. Docherty, Craig White, Livio Gibelli, Matthew K. Borg, James Kermode, Duncan Lockerby

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract / Description of output

A new Micro-Macro-Surrogate (MMS) hybrid method is presented that couples the Direct Simulation Monte Carlo (DSMC) method with Computational Fluid Dynamics (CFD) to simulate low-speed rarefied gas flows. The proposed MMS method incorporates surrogate modelling instead of direct coupling of DSMC data with the CFD, addressing the limitations CFD has in accurately modelling rarefied gas flows, the computational cost of DSMC for low-speed and multiscale flows, as well as the pitfalls of noise in conventional direct coupling approaches. The surrogate models, trained on the DSMC data using Bayesian inference, provide noise-free and accurate corrections to the CFD simulation enabling it to capture the non-continuum physics. The MMS hybrid approach is validated by simulating low-speed, steady-state, force-driven rarefied gas flows in a canonical 1D parallel-plate system, where corrections to the boundary conditions and stress tensor are considered and shows excellent agreement with DSMC benchmark results. A comparison with the typical domain decomposition DSMC-CFD hybrid method is also presented, to demonstrate the advantages of noise-avoidance in the proposed approach. The method also inherently captures the uncertainty arising from micro-model fluctuations, allowing for the quantification of noise-related uncertainty in the predictions. The proposed MMS method demonstrates the potential to enable multiscale simulations where CFD is inaccurate and DSMC is prohibitively expensive.
Original languageEnglish
Article number113500
JournalJournal of Computational Physics
Volume520
Early online date11 Oct 2024
DOIs
Publication statusE-pub ahead of print - 11 Oct 2024

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