Unveiling the Catalytic Origin of Nanocrystalline Yttrium Ruthenate Pyrochlore as a Bifunctional Electrocatalyst for Zn–Air Batteries

Park, Joohyuk; Park, Minjoon; Nam, Gyutae; Kim, Min; Cho, Jaephil

doi:10.1021/acs.nanolett.7b01812

Cited by 79 publications

(76 citation statements)

References 41 publications

(67 reference statements)

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“…[6,7] In an acidic environment, however, only a limited number of OER catalysts are known to operate in a stable way. This has already led to the development of several single-phase and multiphase oxides such as double perovskites Ba 2 MIrO 6 (M = Y, La, Ce, Pr, Nd, and Tb), [10] pyrochlores Y 2 Ir 2 O 7 , [11] [12] The fabrication of highly active and robust hexagonal ruthenium oxide nanosheets for the electrocatalytic oxygen evolution reaction (OER) in an acidic environment is reported. [8] While iridium oxides are more robust, ruthenium oxides exhibit better performance.…”

Section: Introductionmentioning

confidence: 99%

Ruthenium Oxide Nanosheets for Enhanced Oxygen Evolution Catalysis in Acidic Medium

Laha

Lee

Podjaski

et al. 2019

Advanced Energy Materials

165

147

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The fabrication of highly active and robust hexagonal ruthenium oxide nanosheets for the electrocatalytic oxygen evolution reaction (OER) in an acidic environment is reported. The ruthenate nanosheets exhibit the best OER activity of all solution‐processed acid medium electrocatalysts reported to date, reaching 10 mA cm−2 at an overpotential of only ≈255 mV. The nanosheets also demonstrate robustness under harsh oxidizing conditions. Theoretical calculations give insights into the OER mechanism and reveal that the edges are the origin of the high OER activity of the nanosheets. Moreover, the post OER analyses indicate, apart from coarsening, no observable change in the morphology of the nanosheets or oxidation states of ruthenium during the electrocatalytic process. Therefore, the present investigation suggests that ruthenate nanosheets are a promising acid medium OER catalyst with application potential in proton exchange membrane electrolyzers and beyond.

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Section: Introductionmentioning

confidence: 99%

Ruthenium Oxide Nanosheets for Enhanced Oxygen Evolution Catalysis in Acidic Medium

Laha

Lee

Podjaski

et al. 2019

Advanced Energy Materials

165

147

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“…The resulted YRO particles exhibited a good bifunctional capability, with a high ORR onset potential of ≈0.85 V versus RHE and a low OER onset potential of ≈1.45 V. The high activity of YRO was attributed to the increased oxidation state of the cations during OER/ORR, leading to a better electron transfer to facilitate the catalysis process. By using this YRO catalyst in rechargeable Zn–O 2 batteries, a low polarization of about 0.22 V was achieved, together with a small charge/discharge potential difference of ≈0.84 V after 200 cycles (Figure c), which were comparable to the Pt/C + IrO 2 composite catalyst . To reveal the underlying mechanism for the improved catalytic activity of YRO particles, in situ X‐ray absorption spectroscopy (XAS) technique was used to investigate the changes on electron configurations and geometric local structures of cations over reaction.…”

Section: Aqueous Secondary Non‐li Metal–o2 Batteriesmentioning

confidence: 99%

“…a) Schematics of the synthesis of the YRO NPs; b) the corresponding SEM image (inset: the magnified SEM image); c) cycling performance of the rechargeable Zn–O 2 batteries at 10 mA cm −2 ; d) schematics of the ORR/OER catalysis processes on YRO. Reproduced with permission . Copyright 2017, American Chemical Society…”

Section: Aqueous Secondary Non‐li Metal–o2 Batteriesmentioning

confidence: 99%

Toward Promising Cathode Catalysts for Nonlithium Metal–Oxygen Batteries

Mei

Liao

Liang

et al. 2019

Advanced Energy Materials

112

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The success of Li–air/O2 batteries has brought extensive attention to the development of various promising non‐Li metal–O2 batteries, such as Zn–O2, Al–O2, Mg–O2 batteries, etc., which have exhibited unique advantages, such as low production cost, high energy density, and much enhanced safety. The versatile non‐Li metal–O2 batteries provide a better opportunity for meeting the practical requirements for sustainable energy supplies in various applications. A high‐performance cathode in non‐Li metal–O2 batteries that can effectively trigger both oxygen reduction and evolution reactions and thus boost the overall battery performance is of great research interest. In this article, a comprehensive review on the development of Li‐free metal–O2 batteries and particularly focusing on the oxygen catalytic cathodes for both primary and secondary non‐Li metal–O2 batteries is carefully performed. The current challenges and potential solutions are also outlined and proposed. Through carefully selecting and rationally designing promising catalytic cathodes, a series of non‐Li metal–oxygen batteries toward practical energy storage applications are highly anticipated.

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“…[1][2][3] Noch wichtiger ist, dass billige Alternativen wie etwa N-dotierter Kohlenstoff sowie unedle Metalle wie Fe,Co, Ni und deren Metalloxide mit Perowskit-, [4,5] Spinell-, [6,7] Brownmillerit- [8,9] und Pyrochlor-Struktur [10,11] auch als Katalysatoren verwendbar sind, was alkalische MABs praktisch attraktiver macht. [4][5][6][7][8][9][10][11] Ein Problem kohlenstoffbasierter Katalysatoren ist die Kohlenstoffoxidation (Korrosion) während des OER-Vorgangs,d ie einen allmählichen Leistungsabfall zur Folge hat. [3] Verglichen mit wasserbasierten MABs arbeiten MABs mit organischen Elektrolyten bei hçheren Spannungen, sie haben jedoch schwerwiegende Probleme mit der Lebensdauer aufgrund des ständigen Angriffs von H 2 Ound CO 2 (aus der Luft) auf die organischen Elektrolyte,d urch einen allmählichen Verlust an organischen Elektrolyten sowie infolge der Massetransportbegrenzung durch die Bildung fester Produkte (zum Beispiel Li 2 O 2 )w ährend der elektrochemischen Reduktion von Sauerstoff,w as zu einer sehr schlechten Reversibilitätf ührt.…”

unclassified

Ein aktiver und widerstandsfähiger difunktioneller Sauerstoff‐Elektrokatalysator durch kohlenstofffreie hierarchische Funktionalisierung

Huang

2017

Angewandte Chemie

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In einer hierarchisch funktionalisierten Hybridelektrode für Zn‐Luft‐Batterien, die keinen Kohlenstoff benötigt, dient ein bei der Sauerstoffentwicklung (OER) aktives, poröses, leitfähiges und korrosionsbeständiges Nitrid, Ni3FeN, als Trägermaterial für bei der Sauerstoffreduktion (ORR) wirksame geordnete Fe3Pt‐NPs. Die Porosität des Ni3FeN‐Substrats ist entscheidend für eine hohe OER‐Aktivität.

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Unveiling the Catalytic Origin of Nanocrystalline Yttrium Ruthenate Pyrochlore as a Bifunctional Electrocatalyst for Zn–Air Batteries

Cited by 79 publications

References 41 publications

Ruthenium Oxide Nanosheets for Enhanced Oxygen Evolution Catalysis in Acidic Medium

Ruthenium Oxide Nanosheets for Enhanced Oxygen Evolution Catalysis in Acidic Medium

Toward Promising Cathode Catalysts for Nonlithium Metal–Oxygen Batteries

Ein aktiver und widerstandsfähiger difunktioneller Sauerstoff‐Elektrokatalysator durch kohlenstofffreie hierarchische Funktionalisierung

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