Physics-informed neural networks for passive scalar emission and transport
Physics-informed neural networks for passive scalar emission and transport
Accurate modeling of harmful pollutant concentrations is an important field of interest for protecting public health and the environment. In this study, physics-informed neural networks (PINNs) are applied to a low Reynolds number, time-averaged cylinder wake, which interacts with a variety of different passive scalar regimes. The PINN reconstructs both the time-averaged velocity and scalar concentration from limited measurements. In addition to satisfying the incompressible Reynolds-averaged Navier-Stokes (RANS) equations, the reconstructed fields must also obey the time-averaged advection-diffusion equation. This was done to extend the applicability of mean field reconstruction and to lay the foundations for PINNs to be used in more complex passive scalar modeling in future studies, particularly the prediction of pollutant behavior in urban environments. It was found that the PINN could successfully reconstruct the flow fields on a macro-scale in almost all scenarios, having considerable success with first-order quantities and managing to accurately infer the spatial structure of the unknown closure term of the advection-diffusion equation in all cases. When reconstructing scalar source characteristics, the PINN could identify the source location and size in many cases. The results allowed basic guidelines for optimal sensor placement to be described to inform future studies, and suggests ways in which this technique could be developed to contribute to future air quality forecasting models.
Rawden, Joshua Ian
c55b31ff-a5bc-481f-b660-5ab7d9f2c077
Vanderwel, Christina
fbc030f0-1822-4c3f-8e90-87f3cd8372bb
Symon, Sean
2e1580c3-ba27-46e8-9736-531099f3d850
Rawden, Joshua Ian
c55b31ff-a5bc-481f-b660-5ab7d9f2c077
Vanderwel, Christina
fbc030f0-1822-4c3f-8e90-87f3cd8372bb
Symon, Sean
2e1580c3-ba27-46e8-9736-531099f3d850
Rawden, Joshua Ian, Vanderwel, Christina and Symon, Sean
(2026)
Physics-informed neural networks for passive scalar emission and transport.
Physical Review Fluids.
(doi:10.1103/wjlv-sy4j).
Abstract
Accurate modeling of harmful pollutant concentrations is an important field of interest for protecting public health and the environment. In this study, physics-informed neural networks (PINNs) are applied to a low Reynolds number, time-averaged cylinder wake, which interacts with a variety of different passive scalar regimes. The PINN reconstructs both the time-averaged velocity and scalar concentration from limited measurements. In addition to satisfying the incompressible Reynolds-averaged Navier-Stokes (RANS) equations, the reconstructed fields must also obey the time-averaged advection-diffusion equation. This was done to extend the applicability of mean field reconstruction and to lay the foundations for PINNs to be used in more complex passive scalar modeling in future studies, particularly the prediction of pollutant behavior in urban environments. It was found that the PINN could successfully reconstruct the flow fields on a macro-scale in almost all scenarios, having considerable success with first-order quantities and managing to accurately infer the spatial structure of the unknown closure term of the advection-diffusion equation in all cases. When reconstructing scalar source characteristics, the PINN could identify the source location and size in many cases. The results allowed basic guidelines for optimal sensor placement to be described to inform future studies, and suggests ways in which this technique could be developed to contribute to future air quality forecasting models.
Text
FD10304_4_
- Accepted Manuscript
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e-pub ahead of print date: 12 February 2026
Identifiers
Local EPrints ID: 509682
URI: http://eprints.soton.ac.uk/id/eprint/509682
ISSN: 2469-990X
PURE UUID: 41453ee2-610f-4464-b87c-09dd324bc0af
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Date deposited: 02 Mar 2026 17:42
Last modified: 03 Mar 2026 03:18
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Author:
Joshua Ian Rawden
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