A Critical Review of Modeling Transport Phenomena in Polymer-Electrolyte Fuel Cells

Weber, Adam Z.; Borup, Rodney L.; Darling, Robert M.; Das, Prodip K.; Dursch, Thomas J.; Gu, Wenbin; Harvey, David; Kusoglu, Ahmet; Litster, Shawn; Mench, Matthew M.; Mukundan, Rangachary; Owejan, Jon P.; Pharoah, Jon G.; Secanell, Marc; Zenyuk, Iryna V.

doi:10.1149/2.0751412jes

Cited by 509 publications

(437 citation statements)

References 501 publications

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“…8,9 Modeling and simulation are expected to improve the associated issues. [10][11][12] At the same time, non-noble metal catalysts, oxide catalysts, and carbon alloys are being actively researched. 13,14 The Pt loading in the anode catalyst layer is also expected to be reduced after Pt reduction is realized at the cathode.…”

Section: Future Fcv Technologies and Infrastructurementioning

confidence: 99%

Toyota MIRAI Fuel Cell Vehicle and Progress Toward a Future Hydrogen Society

2015

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This article presents a high-level overview of the various technological advances that were performed to enable the commercialization of the Toyota MIRAI fuel cell vehicle. The article describes the innovations made in flow-field structure, catalyst layer structure and composition, various stack components, the hydrogen storage tank, and in streamlining the humidification process. Finally, the article highlights the importance of leveraging mass manufactured parts from prior generations/platforms to the maximum extent possible to achieve the requisite cost reductions and concludes with some thoughts on the future of fuel cell vehicles, and the necessity for a concerted effort to develop a hydrogen fueling infrastructure.

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Section: Future Fcv Technologies and Infrastructurementioning

confidence: 99%

Toyota MIRAI Fuel Cell Vehicle and Progress Toward a Future Hydrogen Society

2015

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“…As can be seen, the reaction distribution within either CL is very narrow and close to the membrane, which is indicative of strong ohmic limitations. 37,38 This also indicates a poor utilization of ORR catalyst within the cCL, especially near the cMPL, which would mean increases in the cCL thickness or effective catalyst loading will not improve performance. This is somewhat different than in PEMFCs, where at high current density the reaction distribution is closer to the cCL/cMPL interface due to oxygen transport limitations.…”

Section: Variablementioning

confidence: 99%

Elucidating Performance Limitations in Alkaline-Exchange- Membrane Fuel Cells

Shiau

Zenyuk

Weber

2017

J. Electrochem. Soc.

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Water management is a serious concern for alkaline-exchange-membrane fuel cells (AEMFCs) because water is a reactant in the alkaline oxygen-reduction reaction and hydroxide conduction in alkaline-exchange membranes is highly hydration dependent. In this paper, we develop and use a multiphysics, multiphase model to explore water management in AEMFCs. We demonstrate that the low performance is mostly caused by extremely non-uniform distribution of water in the ionomer phase. A sensitivity analysis of design parameters including humidification strategies, membrane properties, and water transport resistance was undertaken to explore possible optimization strategies. Furthermore, the strategy and issues of reducing bicarbonate/carbonate buildup in the membrane-electrode assembly with CO 2 from air is demonstrated based on the model prediction. Overall, mathematical modeling is used to explore trends and strategies to overcome performance bottlenecks and help enable AEMFC commercialization. Among existing fuel-cell types, alkaline-exchange-membrane fuel cells (AEMFCs) or hydroxide-exchange-membrane fuel cells (HEMFCs) have intriguing features as compared to proton-exchangemembrane fuel cells (PEMFCs). Their advantage is mainly the possibility of using non-noble catalysts due to faster oxygenreduction-reaction (ORR) kinetics in alkaline media than in acidic media 1-4 as well as perhaps the use of less expensive hydrocarbon membranes. Disadvantages of AEMFCs include lower hydrogenoxidation-reaction (HOR) kinetics, more complicated water management, and lower intrinsic conductivity for hydroxide compared to proton transport. [5][6][7][8][9][10][11][12][13] In addition, CO 2 in the air reacts with hydroxide ions to form bicarbonate and carbonate ions, possibly hindering the terrestrial development of AEMFCs by removing hydroxide available for HOR and further limiting hydroxide conductivity. 14,15 Compared to conventional alkaline fuel cells (i.e., using a liquid electrolyte of potassium hydroxide), AEMFCs use a polymeric membrane and should have better tolerance for CO 2 because the precipitate K 2 CO 3 is absent in the AEMFC due to the lack of mobile cations in the membrane. 16 However, AEMFCs still suffer a decline in performance due to bicarbonate/carbonate formation in the membrane and catalyst layers (CLs) leading to additional ohmic and kinetic losses. [13][14][15] In an AEMFC, the following electrochemical reactions occur in the CLs as follows:Net :Hydrogen combines with hydroxide ions to produce water in the anode. Oxygen reacts with water to generate hydroxide ions in the cathode. Along with the transport of ions from cathode to anode, electro-osmosis moves water from cathode to anode. As shown in the reactions, AEMFCs are expected to have more complicated water management. Water production by the HOR and electro-osmosis may cause flooding in the anode. Since water is a stoichiometric reactant at the cathode, dehydration may occur and limit ORR kinetics as well as ionic conduction in the membrane and cathode CL, ...

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“…Therefore, a more detailed modelling approach, such as the pore network modeling or full morphology (Lattice Boltzmann) simulations [56][57][58][59][60] would bring a more realistic description of the phenomena.…”

Section: Resultsmentioning

confidence: 99%

Advanced Water Management in PEFCs: Diffusion Layers with Patterned Wettability

Forner‐Cuenca

Biesdorf

Lamibrac

et al. 2016

J. Electrochem. Soc.

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In this paper, we present an experimental study on the development of gas diffusion layer (GDL) materials for fuel cells with dedicated water removal pathways generated using radiation induced grafting of hydrophilic compounds onto the hydrophobic polymer coating. The impact of several material parameters was studied: the carbon substrate type, the coating load, the grafted chemical compound and the pattern design (width and separation of the hydrophilic pathways). The corresponding materials were characterized for their capillary pressure characteristic during water imbibition experiments, in which we also evidenced the differences between injection from a narrow distribution channel in the center of the material (and thus strongly relying on lateral transport) and homogeneous injection from one face of the material. All materials parameters were observed to have a significant influence on the water distribution. In particular, the type of substrate has a dramatic impact, with results ranging from a nearly perfect separation of water between hydrophilic and hydrophobic domains for substrates having a narrow pore size distribution to a fully random imbibition of the material for substrates having a broad pore size distribution.

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A Critical Review of Modeling Transport Phenomena in Polymer-Electrolyte Fuel Cells

Cited by 509 publications

References 501 publications

Toyota MIRAI Fuel Cell Vehicle and Progress Toward a Future Hydrogen Society

Toyota MIRAI Fuel Cell Vehicle and Progress Toward a Future Hydrogen Society

Elucidating Performance Limitations in Alkaline-Exchange- Membrane Fuel Cells

Advanced Water Management in PEFCs: Diffusion Layers with Patterned Wettability

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