A review of <scp>PEM</scp> fuel cell durability: materials degradation, local heterogeneities of aging and possible mitigation strategies

Dubau, Laëtitia; Castanheira, Luis; Maillard, Frédéric; Chatenet, Marian; Lottin, Olivier; Maranzana, Gaël; Dillet, Jérôme; Lamibrac, Adrien; Perrin, Jean‐Christophe; Moukheiber, E.; ElKaddouri, Assma; Moor, Gilles de; Bas, Corine; Flandin, Lionel; Caqué, Nicolas

doi:10.1002/wene.113

Cited by 274 publications

(238 citation statements)

References 95 publications

(265 reference statements)

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“…The initiation and leak growth periods of the tests with PITM resemble those of the constant RH tests, despite being exposed to baseline AMDT conditions, including RH cycling. The longer leak growth times at constant RH and with PITM confirm that MEAs are able to operate for a relatively long time despite the presence of small leaks, when the conditions are favorable; 59 i.e., low mechanical stress in the case of constant RH and low chemical stress in the case of PITM.…”

Section: Resultsmentioning

confidence: 61%

Accelerated Membrane Durability Testing of Heavy Duty Fuel Cells

Macauley

Alavijeh

Watson

et al. 2014

J. Electrochem. Soc.

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Regular durability testing of heavy duty fuel cell systems for transit bus application requires several thousand hours of operation, which is costly and time consuming. Alternatively, accelerated durability tests are able to generate failure modes observed in field operation in a compressed time period, by applying enhanced levels of stress. The objective of the present work is to design and validate an accelerated membrane durability test (AMDT) for heavy duty fuel cells under bus related conditions. The proposed AMDT generates bus relevant membrane failure modes in a few hundred hours, which is more than an order of magnitude faster than for regular duty cycle testing. Elevated voltage, temperature, and oxidant levels are used to accelerate membrane chemical stress, while relative humidity (RH) cycling is used to induce mechanical stress. RH cycling is found to significantly reduce membrane life-time compared to constant RH conditions. The role of a platinum band in the membrane is investigated and membranes with Pt bands demonstrate a considerable life-time extension under AMDT conditions, with minimal membrane degradation. Overall, this research serves to establish a benchmark AMDT that can rapidly and reliably evaluate membrane stability under simulated heavy duty fuel cell conditions.

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Section: Resultsmentioning

confidence: 61%

Accelerated Membrane Durability Testing of Heavy Duty Fuel Cells

Macauley

Alavijeh

Watson

et al. 2014

J. Electrochem. Soc.

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“…Firstly, PEMFC materials [3][4][5] and systems 6,7 are not sufficiently durable in operation. Secondly, their catalysts are based on expensive and rare elements (generally platinum or platinum-alloys).…”

mentioning

confidence: 99%

Effects of Pd Nanoparticle Size and Solution Reducer Strength on Pd/C Electrocatalyst Stability in Alkaline Electrolyte

Zadick

Dubau

Demirci

et al. 2016

J. Electrochem. Soc.

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“…Liang et al [229] found water electrolysis would take place while cell reversal results in significant performance degradation. Meanwhile, the load variation process of PEMFCs is a very complex phenomenon, which is affected by many parameters, such as reactant stoichiometric ratio [216,230], reactant flow rate [231], loading range [220], loading speed [220], anode and cathode humidity [230][231][232], anode and cathode pressure [230] and proper reactant supply system [233].…”

Section: Load Variation Processesmentioning

confidence: 99%

Recent Progress on the Key Materials and Components for Proton Exchange Membrane Fuel Cells in Vehicle Applications

Wang

Peng

et al. 2016

Energies

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Fuel cells are the most clean and efficient power source for vehicles. In particular, proton exchange membrane fuel cells (PEMFCs) are the most promising candidate for automobile applications due to their rapid start-up and low-temperature operation. Through extensive global research efforts in the latest decade, the performance of PEMFCs, including energy efficiency, volumetric and mass power density, and low temperature startup ability, have achieved significant breakthroughs. In 2014, fuel cell powered vehicles were introduced into the market by several prominent vehicle companies. However, the low durability and high cost of PEMFC systems are still the main obstacles for large-scale industrialization of this technology. The key materials and components used in PEMFCs greatly affect their durability and cost. In this review, the technical progress of key materials and components for PEMFCs has been summarized and critically discussed, including topics such as the membrane, catalyst layer, gas diffusion layer, and bipolar plate. The development of high-durability processing technologies is also introduced. Finally, this review is concluded with personal perspectives on the future research directions of this area.

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A review of PEM fuel cell durability: materials degradation, local heterogeneities of aging and possible mitigation strategies

Cited by 274 publications

References 95 publications

Accelerated Membrane Durability Testing of Heavy Duty Fuel Cells

Accelerated Membrane Durability Testing of Heavy Duty Fuel Cells

Effects of Pd Nanoparticle Size and Solution Reducer Strength on Pd/C Electrocatalyst Stability in Alkaline Electrolyte

Recent Progress on the Key Materials and Components for Proton Exchange Membrane Fuel Cells in Vehicle Applications

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