A review on performance degradation of proton exchange membrane fuel cells during startup and shutdown processes: Causes, consequences, and mitigation strategies

Yu, Yi; Li, Hui; Wang, Haijiang; Yuan, Xiao‐Zi; Wang, Guangjin; Pan, Mu

doi:10.1016/j.jpowsour.2012.01.059

Cited by 256 publications

(155 citation statements)

References 98 publications

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“…This is confirmed e.g. in the review of PEMFC degradation processes published by Yu et al 4 The process which is induced by the formation of a hydrogen oxygen front on the anode side upon hydrogen admission after longer standstill can cause potential excursions of the cathode side to potentials between 1.4 and 1.75 V.5 Accordingly, the common tests suites published by US Department of Energy (DoE) and the Fuel Cell Commercialisation Conference of Japan (FCCJ), respectively, comprise both similar accelerated carbon corrosion test protocols based on fast triangular potential cycling to 1.5 V.Carbon corrosion is, however, not the only degradation mechanism occurring in PEMFC. Another important cause of degradation is the loss of platinum surface area by effects like platinum dissolution and * Electrochemical Society Member.…”

supporting

confidence: 71%

supporting

confidence: 57%

“…From this results a difference of the integrated carbon mass loss during a stress phase. Carbon mass lost rates were therefore determined by integrating the mass loss over each stress phase and dividing by the stress phase duration of 2000 s. [4] Herein, dm Csp /dt is the average carbon mass loss rate per second during a particular stress phase sp, M C = 12.011 g mol −1 is the atomic mass of carbon. K MS is the mass spectrometer calibration constant defined in Equation 3, I M S 44 (t) is the time dependent MS ion current of fragment m/z = 44 and t sp = 2000 s the duration of the stress phase.…”

Section: Resultsmentioning

confidence: 99%

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DEMS and Online Mass Spectrometry Studies of the Carbon Support Corrosion under Various Polymer Electrolyte Membrane Fuel Cell Operating Conditions

Cremers

Jurzinsky

Meier

et al. 2018

J. Electrochem. Soc.

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Differential electrochemical mass spectrometry as well as online mass spectrometry in combination with singe cell testing has been used to study carbon corrosion of typical carbon materials discussed as support for electro-catalyst in fuel cells, e.g. carbon blacks or carbon nanotubes. Beside standard tests used to study the stability under automotive LT-PEMFC conditions, additional tests were performed to try to test the stability under the operating conditions of high temperature polymer electrolyte membrane fuel cells (HT-PEMFC). It was shown that under LT-PEMFC conditions a strong catalytic effect of platinum on the carbon corrosion rate is observable. High temperatures in HT-PEMFC do accelerate the corrosion rate. It was further found that corrosion does not only occur at high potentials but also to a minor amount at lower potentials. This low potential corrosion is in particular observed after a prior potential excursion of the electrode indicating that such excursions do not only lead to the direct corrosion of the support but also to the formation of unstable surface groups, which can be removed subsequently. Throughout all tests, CNT exhibited a higher stability than the tested carbon blacks. In single cell testing, the contribution of other carbon materials in particular the MPL was evaluated. It was found that it is present but small compared to the catalyst support itself. In order to reduce the expenditure of platinum group metals in polymer electrolyte membrane fuel cells the dispersion of the catalyst on a conductive support is the current state-of the art. Only few examples do not follow this approach. Most prominent among the exemptions is the Nano-Structured Thin Film (NSTF) type of catalyst developed by 3M.1 For most applications, carbon has become, however, a sort of standard support material. To accomplish the goal to reduce costs for the fuel cells, inexpensive carbon black materials like Vulcan XC72R from Cabot are used most often. However, as carbon in presence of water is thermodynamically unstable for potentials higher than 0.207 V 2 carbon corrosion can become an issue if the oxidation of the carbon is not strongly kinetically hindered e.g. via high degrees of graphitization. Consequently, carbon materials exhibiting such high degrees of graphitization like carbon nanotubes or graphene have attracted attention as alternative supports.The focus of the research on carbon corrosion is on LT-PEMFC for automotive application. With respect to carbon corrosion the reversed current decay mechanism proposed by Reiser et al.3 is an accepted cause for this type of degradation processes. This is confirmed e.g. in the review of PEMFC degradation processes published by Yu et al. 4 The process which is induced by the formation of a hydrogen oxygen front on the anode side upon hydrogen admission after longer standstill can cause potential excursions of the cathode side to potentials between 1.4 and 1.75 V.5 Accordingly, the common tests suites published by US Department of Energy (DoE) and the Fuel Ce...

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supporting

confidence: 71%

supporting

confidence: 57%

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

DEMS and Online Mass Spectrometry Studies of the Carbon Support Corrosion under Various Polymer Electrolyte Membrane Fuel Cell Operating Conditions

Cremers

Jurzinsky

Meier

et al. 2018

J. Electrochem. Soc.

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“…The cathode degradation mechanism has also been studied to improve the MEA durability, which becomes more serious issue [1,[36][37][38][39]. Therefore, the nanoscopic spatial place and mechanism of the dissolution and deterioration of the Pt/C cathode electrocatalysts in MEAs should be uncovered to develop next-generation PEFCs with high durability.…”

Section: Introductionmentioning

confidence: 99%

Key Factors Affecting the Performance and Durability of Cathode Electrocatalysts in Polymer Electrolyte Fuel Cells Characterized by In Situ Real Time and Spatially Resolved XAFS Techniques

2014

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The account article treats with the characterizations of the structural and electronic transformations of Pt/C, Pt 3 Co/C, and Pt 3 Ni/C cathode electrocatalysts in polymer electrolyte fuel cells (PEFCs) involving Pt charging/discharging, Pt-O bond formation/breaking, and Pt-Pt bond breaking/reformation in cathode potential-jump processes and the rate constants of those transformations in the surface reaction sequences on the cathode electrocatalysts by in situ time-resolved X-ray absorption fine structure (XAFS) method. Spatially heterogeneous issue and mechanism for the Pt oxidation and degradation of Pt/C cathode electrocatalyst layers in PEFCs under the operating conditions, which should be uncovered for development of next-generation PEFCs, were also characterized by a scanning nano-XAFS mapping method and a laminography-XAFS method, respectively for 2D and 3D visualizations of Pt chemical species in Pt/C cathode electrocatalyst layers. These XAFS techniques provided new insights into critical issues affecting the performance and property of practical PEFCs under the operating conditions.

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“…Including oxygen evolution reaction (OER) catalysts with the oxygen reduction reaction (ORR) active Pt, can minimize the extent of the potential transients associated with SUSD events, and thus minimize the damage caused by them. Atanasoski,6 first proposed this materials solution to the RCDM problem, which was in contrast to the many system based approaches (which are listed in the review by Yu et al 7 ). Ir and Ru are the only OER catalysts stable in the acidic conditions of the polymer electrolyte membrane fuel cell (PEMFC), with Ru being the less expensive and more active, but less stable of the two.…”

mentioning

confidence: 99%

Screening Bifunctional Pt Based NSTF Catalysts for Durability with the Rotating Disk Electrode: The Effect of Ir and Ru

Crowtz

Dahn

2018

J. Electrochem. Soc.

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Various amounts of Ir (<20 μg cm −2 ) and Ru (up to 12 μg cm −2 ) on a consistent base Pt loading of 85 μg cm −2 , were sputter deposited on a nanostructured thin film catalyst support to mimic a hydrogen fuel cell's cathode catalyst. The nanostructured support was grown on glassy carbon disks designed for a rotating disk electrode, which was used to simulate what happens to a fuel cell cathode during repeated start-up, operation, and shut-down. The testing protocol subjected the catalyst to a minimum potential of 0.65 V RHE and a maximum between 1.53 and 1.8 V RHE . The upper potential was achieved with a galvanostatic hold which is an alternative way to simulate potential transients on the cathode caused by start-up and shut-down. Increasing Ir loading improved the durability of both oxygen reduction reaction (ORR) and oxygen evolution reaction (OER) activity. When combined with Ir, Ru provided no benefit to OER durability except at an Ir loading of 10 μg cm −2 . Ru addition (no Ir present) improved the ORR durability compared to pure Pt. ORR durability was not influenced by Ru addition to Ir-containing samples. In general, ORR durability showed no dependence on Ru loading for all the Ru containing samples and ORR activity was decreased by OER catalyst addition, though more so for Ir than Ru.

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A review on performance degradation of proton exchange membrane fuel cells during startup and shutdown processes: Causes, consequences, and mitigation strategies

Cited by 256 publications

References 98 publications

DEMS and Online Mass Spectrometry Studies of the Carbon Support Corrosion under Various Polymer Electrolyte Membrane Fuel Cell Operating Conditions

DEMS and Online Mass Spectrometry Studies of the Carbon Support Corrosion under Various Polymer Electrolyte Membrane Fuel Cell Operating Conditions

Key Factors Affecting the Performance and Durability of Cathode Electrocatalysts in Polymer Electrolyte Fuel Cells Characterized by In Situ Real Time and Spatially Resolved XAFS Techniques

Screening Bifunctional Pt Based NSTF Catalysts for Durability with the Rotating Disk Electrode: The Effect of Ir and Ru

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