Related papers: Particle clustering in turbulence: Prediction of spatial and statistical properties with deep learning

Particle clustering in turbulence: Prediction of spatial and statistical properties with deep learning

URL: http://arxiv.org/abs/2210.02339v2
Date: Sat, 6 Jan 2024 22:30:31 GMT
Title: Particle clustering in turbulence: Prediction of spatial and statistical properties with deep learning
Authors: Yan-Mong Chan, Natascha Manger, Yin Li, Chao-Chin Yang, Zhaohuan Zhu, Philip J. Armitage and Shirley Ho
Abstract summary: We simulate the dynamics of particles in the Epstein drag regime within a periodic domain of isotropic forced hydrodynamic turbulence. We train a U-Net deep learning model to predict gridded representations of the particle density and velocity fields, given as input the corresponding fluid fields. Our results suggest that, given appropriately expanded training data, deep learning could complement direct numerical simulations in predicting particle clustering within turbulent flows.
Score: 6.91821181311687
License: http://creativecommons.org/licenses/by/4.0/
Abstract: We investigate the utility of deep learning for modeling the clustering of particles that are aerodynamically coupled to turbulent fluids. Using a Lagrangian particle module within the Athena++ hydrodynamics code, we simulate the dynamics of particles in the Epstein drag regime within a periodic domain of isotropic forced hydrodynamic turbulence. This setup is an idealized model relevant to the collisional growth of micron to mm-sized dust particles in early stage planet formation. The simulation data are used to train a U-Net deep learning model to predict gridded three-dimensional representations of the particle density and velocity fields, given as input the corresponding fluid fields. The trained model qualitatively captures the filamentary structure of clustered particles in a highly non-linear regime. We assess model fidelity by calculating metrics of the density field (the radial distribution function) and of the velocity field (the relative velocity and the relative radial velocity between particles). Although trained only on the spatial fields, the model predicts these statistical quantities with errors that are typically <10%. Our results suggest that, given appropriately expanded training data, deep learning could complement direct numerical simulations in predicting particle clustering within turbulent flows.

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