A non-precious metal hydrogen catalyst in a commercial polymer electrolyte membrane electrolyser

King, Laurie A.; Hubert, McKenzie A.; Capuano, Christopher; Manco, Judith; Danilovic, Nemanja; Valle, Eduardo; Hellstern, Thomas R.; Ayers, Katherine E.; Jaramillo, Thomas F.

doi:10.1038/s41565-019-0550-7

Cited by 232 publications

(185 citation statements)

References 32 publications

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“…The line in Fig. 7 represents the performance of a typical current commercial PEM water electrolyzer [98]. It is thus a current target line for the AEM water electrolysis.…”

Section: Performance Of Commercial Membranes In Anionmentioning

confidence: 99%

“…The voltages at Fig. 6 Comparison of (a) the highest current densities observed for selected AEM manufacturers (indicated in the x-axis description) [16,17,69,82,88,93,97,98] and (b) average current densities observed for electrolyte type (indicated in the x-axis description) @ 1.8 V cell voltage in alkaline electrolytes. Orion membranes are not included, because the data base is too small yet.…”

Section: Performance Of Commercial Membranes In Anionmentioning

confidence: 99%

“…7 Performances of AEM water electrolysis systems: (a) based on the use of PGM or non-PGM catalysts, (b) based on the feed, and (c) based on the operation temperature. The dotted line represents the performance of a commercial PEM water electrolysis system [98] and therefore indicates a current performance target for AEM water electrolyzers with pure water as feed. The reader is referred to the online version for color coding.…”

Section: Performance Of Commercial Membranes In Anionmentioning

confidence: 99%

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Overview: State-of-the Art Commercial Membranes for Anion Exchange Membrane Water Electrolysis

Henkensmeier

Najibah

Harms³

et al. 2020

Journal of Electrochemical Energy Conversion and Storage

197

205

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One promising way to store and distribute large amounts of renewable energy is water electrolysis, coupled with transport of hydrogen in the gas grid and storage in tanks and caverns. The intermittent availability of renewal energy makes it difficult to integrate it with established alkaline water electrolysis technology. Proton exchange membrane (PEM) water electrolysis is promising, but limited by the necessity to use expensive platinum and iridium catalysts. The expected solution is anion exchange membrane (AEM) water electrolysis, which combines the use of cheap and abundant catalyst materials with the advantages of PEM water electrolysis, namely a low foot print, large operational capacity, and fast response to changing operating conditions. The key component for AEM water electrolysis is a cheap, stable, gas tight and highly hydroxide conductive polymeric AEM. Here we present target values and technical requirements for AEMs, discuss the chemical structures involved and the related degradation pathways, and give an overview over the most prominent and promising commercial AEMs (Fumatech Fumasep® FAA3, Tokuyama A201, Ionomr Aemion™, Dioxide materials Sustainion®, and membranes commercialized by Orion Polymer), and review their properties and performances of water electrolyzers using these membranes.

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“…The line in Fig. 7 represents the performance of a typical current commercial PEM water electrolyzer [98]. It is thus a current target line for the AEM water electrolysis.…”

Section: Performance Of Commercial Membranes In Anionmentioning

confidence: 99%

Section: Performance Of Commercial Membranes In Anionmentioning

confidence: 99%

Section: Performance Of Commercial Membranes In Anionmentioning

confidence: 99%

See 1 more Smart Citation

Overview: State-of-the Art Commercial Membranes for Anion Exchange Membrane Water Electrolysis

Henkensmeier

Najibah

Harms³

et al. 2020

Journal of Electrochemical Energy Conversion and Storage

197

205

View full text Add to dashboard Cite

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“…Electrochemical splitting water into H 2 is considered as a promising technology for storing renewable and sustainable energy 1 – 7 . Acidic proton exchange membrane (PEM) water electrolyzers is highly desirable because the reaction rate in acidic electrolyte is three or more orders of magnitudes speedier than pH-neutral and alkaline electrolyzers owing to its higher voltage efficiency, more compact designing system, lower ohmic loss, and wider partial load range 8 – 11 . For decades, anode catalyst for PEM is mainly concentrated on IrO 2 with the compromise between stability and activity in acidic electrolyte 12 – 17 .…”

Section: Introductionmentioning

confidence: 99%

Dopants fixation of Ruthenium for boosting acidic oxygen evolution stability and activity

et al. 2020

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Designing highly durable and active electrocatalysts applied in polymer electrolyte membrane (PEM) electrolyzer for the oxygen evolution reaction remains a grand challenge due to the high dissolution of catalysts in acidic electrolyte. Hindering formation of oxygen vacancies by tuning the electronic structure of catalysts to improve the durability and activity in acidic electrolyte was theoretically effective but rarely reported. Herein we demonstrated rationally tuning electronic structure of RuO2 with introducing W and Er, which significantly increased oxygen vacancy formation energy. The representative W0.2Er0.1Ru0.7O2-δ required a super-low overpotential of 168 mV (10 mA cm−2) accompanied with a record stability of 500 h in acidic electrolyte. More remarkably, it could operate steadily for 120 h (100 mA cm−2) in PEM device. Density functional theory calculations revealed co-doping of W and Er tuned electronic structure of RuO2 by charge redistribution, which significantly prohibited formation of soluble Rux>4 and lowered adsorption energies for oxygen intermediates.

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“…Meter-size large-scale nanocluster textiles for industrial applications Finally, we discuss the scalability of our proposed method and the preparation of meter-size large-scale textiles, combining electrospinning and sputtering techniques for commercial scale applications. 36 We have shown that 3 Â 3 cm laboratory scale textile can be fabricated (Fig. 1), but it should be possible to fabricate larger textiles with electrospinning and sputtering techniques because meter-scale non-woven polymer textiles are oen industrially fabricated by electrospinning and roll-based consecutive sputtering techniques for large area sputtering, as schematically illustrated in Fig.…”

Section: Surface Chemical State and Catalytic Active Sitesmentioning

confidence: 99%

Freestanding interconnected nanocluster textiles for efficient oxygen evolution reaction

et al. 2020

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A non-precious metal hydrogen catalyst in a commercial polymer electrolyte membrane electrolyser

Cited by 232 publications

References 32 publications

Overview: State-of-the Art Commercial Membranes for Anion Exchange Membrane Water Electrolysis

Overview: State-of-the Art Commercial Membranes for Anion Exchange Membrane Water Electrolysis

Dopants fixation of Ruthenium for boosting acidic oxygen evolution stability and activity

Freestanding interconnected nanocluster textiles for efficient oxygen evolution reaction

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