Micro-Scale Analysis of Liquid Water Breakthrough inside Gas Diffusion Layer for PEMFC Using X-ray Computed Tomography and Lattice Boltzmann Method

Satjaritanun, Pongsarun; Weidner, John W.; Hirano, Shin‐ichi; Lu, Zujie; Khunatorn, Yottana; Ogawa, Shigeo; Litster, Shawn; Shum, Andrew D.; Zenyuk, Iryna V.; Shimpalee, Sirivatch

doi:10.1149/2.0391711jes

Cited by 64 publications

(67 citation statements)

References 74 publications

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“…Jeon and Kim [179] revealed that the compression ratio significantly affects the water transport in the GDL. Most recently, the transport of liquid water inside the GDL was revealed by using LBM [261,262]. The overall LBM predictions of water evolution within the GDL agree well with the in-situ flow visualization from X-ray CT. Zhang et al [68] proposed a 3D LBM to simulate liquid water transport in GDL of PEMFC with electrochemical reaction on the catalyst layer and oxygen diffusion in GDL taken into account in transient state.…”

Section: Accepted Manuscriptsupporting

confidence: 53%

“…Therefore no validation of the pore-scale modeling based on the CL structure has been made to compare the polarization curves from simulation and experimental measurement. Nonetheless, validation of the model based on the comparison of the effective diffusivity, effective conductivity [222] and water distribution in the GDL [261,262] have been attempted.…”

Section: Accepted Manuscriptmentioning

confidence: 99%

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Progress in 3D electrode microstructure modelling for fuel cells and batteries: transport and electrochemical performance

Zhang¹,

Bertei²,

Tariq³

et al. 2019

Prog. Energy

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Electrode microstructure plays an important role in the performance of electrochemical energy devices including fuel cells and batteries. Building a clear understanding of how the performance is affected by the electrode microstructure is necessary to design the optimal electrode microstructure, to achieve better device performance. 3D microstructure modelling enables us to perform simulations directly on a 3D electrode microstructure and thus link structure with performance. This paper provides an extensive review on the current state of the art in 3D microstructure modelling of transport and electrochemical performance for four promising electrochemical energy technologies: solid oxide fuel cells (SOFCs), proton exchange membrane fuel cells (PEMFCs), redox flow batteries (RFBs) and lithium ion batteries (LIBs). Each technology has different electrode microstructures and processes, and thus presents different challenges. The most commonly used modelling methods including the finite element method (FEM) and the finite volume method (FVM) are reviewed, together with the developing lattice Boltzmann method (LBM), with the advantages and disadvantages of each method revealed. Whilst FEM and FVM have been extensively applied in simulating SOFC and LIB electrodes where the methods are capable of dealing with single phase (gas or liquid) transport, they face challenges in simulating the multiphase phenomenon present in PEMFC and some RFB electrodes. LBM is, on the other hand, well suited in simulating gas-liquid two phase flow and applications in PEMFCs and RFBs, as well as single-phase phenomenon in SOFCs and LIBs. The review also points to current challenges in 3D microstructure modelling, including the

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Section: Accepted Manuscriptsupporting

confidence: 53%

Section: Accepted Manuscriptmentioning

confidence: 99%

Progress in 3D electrode microstructure modelling for fuel cells and batteries: transport and electrochemical performance

Zhang¹,

Bertei²,

Tariq³

et al. 2019

Prog. Energy

View full text Add to dashboard Cite

show abstract

“…Recently, great attention has been drawn to pore-scale (PS) modeling to overcome some of the shortcomings of VA GDL models, and improve our understanding of specific transport processes (see, e.g., [43][44][45][46][47][48][49][50][51][52][53][54][55] among others). Furthermore, PS models allow the characterization of effective properties that are extremely difficult to measure experimentally due to the small dimensions of GDLs [23,24,27,[56][57][58][59][60][61][62][63][64][65][66].…”

Section: Accepted Manuscriptmentioning

confidence: 99%

A comparative investigation into the influence of the constitutive model on the prediction of in-plane formability for Nakazima and Marciniak tests

Noder

Butcher

2019

International Journal of Mechanical Sciences

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“…[43][44][45][46][47][48]51,56,61,62,[64][65][66][67]71 Using XCT for membrane analysis is more challegning given the relatively low X-ray attenuation of the polymer. Garzon et al 68 demonstrated that Pt redistribution from the electrodes into the membrane can be captured by XCT.…”

mentioning

confidence: 99%

3D Failure Analysis of Pure Mechanical and Pure Chemical Degradation in Fuel Cell Membranes

Singh

Orfino

Dutta

et al. 2017

J. Electrochem. Soc.

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Lifetime-limiting failure of fuel cell membranes is generally attributed to their chemical and/or mechanical degradation. Although both of these degradation modes occur concurrently during operational duty cycles, their uncoupled investigations can provide useful insights into their individual characteristics and consequential impacts on the overall membrane failure. X-ray computed tomography is emerging as an advantageous tool for fuel cell failure analysis due to its non-destructive and non-invasive 3D imaging capabilities at ambient conditions. In the present work, post-mortem failure analysis of pure mechanical and pure chemical membrane degradation modes is performed three-dimensionally using this technique. A uniquely comprehensive analysis afforded by this technique reveals that membrane failure is almost exclusively characterized by crack formations during mechanical degradation and by severe thinning accompanied by electrode shorting and pinhole formation during chemical degradation, respectively. Catalyst layer cracks, particularly on the cathode side, are found to interact strongly with mechanically induced membrane cracks. The conjoint effect of chemical and mechanical stressors is established as a necessary requirement for: (i) exclusive membrane crack development independent of catalyst layer cracks; and (ii) crack branching during membrane crack propagation. Overall, the membrane failure analysis improves its reliability and quantitative character with the adoption of 3D imaging. The transportation sector is a significant contributor to global greenhouse gas emissions and with ever-growing concerns around the global warming effect, research and development of novel clean energy based automotive solutions is being pursued worldwide. Hydrogen fuel cells have thus far emerged as a promising alternative to fossil fuel based internal combustion engines due to their clean, noisefree, and efficient operation.1 Polymer electrolyte membrane (PEM) fuel cells 2 are widely used in fuel cell electric vehicles (FCEVs) and supply electrical energy from the electrochemical conversion of hydrogen and oxygen (usually supplied as air) into water. In automotive applications, the fluctuating operating conditions due to vehicle dynamics, variations in loads and environmental conditions, startups and shutdowns, fuel starvation, contamination, and freeze-thaw cycles pose significant durability challenges for the PEM fuel cells. 3Understanding the specific durability problems and developing suitable solutions remains a key research focus in automotive PEM fuel cell technology research and is critical to the long-term and large-scale commercial adoption of this technology. Given the complex interplay of multiple physical phenomena that are simultaneously active in an operating PEM fuel cell, various deleterious factors affecting PEM fuel cell components can collectively lead to a gradual performance loss and eventual failure.In PEM fuel cells, the electrodes are separated by a polymeric membrane which allows selective tran...

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Micro-Scale Analysis of Liquid Water Breakthrough inside Gas Diffusion Layer for PEMFC Using X-ray Computed Tomography and Lattice Boltzmann Method

Cited by 64 publications

References 74 publications

Progress in 3D electrode microstructure modelling for fuel cells and batteries: transport and electrochemical performance

Progress in 3D electrode microstructure modelling for fuel cells and batteries: transport and electrochemical performance

A comparative investigation into the influence of the constitutive model on the prediction of in-plane formability for Nakazima and Marciniak tests

3D Failure Analysis of Pure Mechanical and Pure Chemical Degradation in Fuel Cell Membranes

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