Large-scale physically accurate modelling of real proton exchange membrane fuel cell with deep learning-Reference-Cited by-同舟云学术

Large-scale physically accurate modelling of real proton exchange membrane fuel cell with deep learning

Published:2023-02-14 Issue:1 Volume:14 Page:
ISSN:2041-1723
Container-title:Nature Communications
language:en
Short-container-title:Nat Commun

Author:

Wang Ying Da^ORCID,Meyer Quentin,Tang Kunning,McClure James E.^ORCID,White Robin T.,Kelly Stephen T.^ORCID,Crawford Matthew M.,Iacoviello Francesco^ORCID,Brett Dan J. L.^ORCID,Shearing Paul R.^ORCID,Mostaghimi Peyman,Zhao Chuan^ORCID,Armstrong Ryan T.^ORCID

Abstract

AbstractProton exchange membrane fuel cells, consuming hydrogen and oxygen to generate clean electricity and water, suffer acute liquid water challenges. Accurate liquid water modelling is inherently challenging due to the multi-phase, multi-component, reactive dynamics within multi-scale, multi-layered porous media. In addition, currently inadequate imaging and modelling capabilities are limiting simulations to small areas (<1 mm2) or simplified architectures. Herein, an advancement in water modelling is achieved using X-ray micro-computed tomography, deep learned super-resolution, multi-label segmentation, and direct multi-phase simulation. The resulting image is the most resolved domain (16 mm2 with 700 nm voxel resolution) and the largest direct multi-phase flow simulation of a fuel cell. This generalisable approach unveils multi-scale water clustering and transport mechanisms over large dry and flooded areas in the gas diffusion layer and flow fields, paving the way for next generation proton exchange membrane fuel cells with optimised structures and wettabilities.

Publisher

Springer Science and Business Media LLC

Subject

General Physics and Astronomy,General Biochemistry, Genetics and Molecular Biology,General Chemistry,Multidisciplinary

Link

https://www.nature.com/articles/s41467-023-35973-8.pdf

Reference102 articles.

1. Mehta, V. & Cooper, J. S. Review and analysis of PEM fuel cell design and manufacturing. J. Power Sources 114, 32–53 (2003).

2. Nagai, Y. et al. Improving water management in fuel cells through microporous layer modifications: fast operando tomographic imaging of liquid water. J. Power Sources 435, 226809 (2019).

3. Meyer, Q. et al. Multi-Scale Imaging of Polymer Electrolyte Fuel Cells using X-ray Micro- and Nano-Computed Tomography, Transmission Electron Microscopy and Helium-Ion Microscopy. Fuel Cells 19, 35–42 (2019).

4. Owejan, J. P., Gagliardo, J. J., Sergi, J. M., Kandlikar, S. G. & Trabold, T. A. Water management studies in PEM fuel cells, Part I: Fuel cell design and in situ water distributions. Int. J. Hydrog. Energy 34, 3436–3444 (2009).

5. Tolj, I., Bezmalinovic, D. & Barbir, F. Maintaining desired level of relative humidity throughout a fuel cell with spatially variable heat removal rates. Int. J. Hydrog. Energy 36, 13105–13113 (2011).

Cited by 48 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Machine learning for the advancement of membrane science and technology: A critical review;Journal of Membrane Science;2025-01

2. Methods and Instruments | X-Ray Computed Tomography;Encyclopedia of Electrochemical Power Sources;2025

3. Microenvironment engineering of gas-involving energy electrocatalysis and device applications;Coordination Chemistry Reviews;2024-09

4. Micro-CT structures facilitated lattice Boltzmann simulations on the water dynamics in PEMFCs GDL-Gas channel;International Journal of Hydrogen Energy;2024-09

5. Phase separation modeling of water transport in polymer electrolyte membrane fuel cells using the Multiple-Relaxation-Time lattice Boltzmann method;Chemical Engineering Journal;2024-09