Transition Metal Carbides and Nitrides as Electrode Materials for Low Temperature Fuel Cells

Ham, Dong Jin; Lee, Jae Sung

doi:10.3390/en20400873

Cited by 398 publications

(274 citation statements)

References 112 publications

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“…[58] They are more difficult to etch at higher overpotential where most transition-metals tend to dissolve.N itrogen can be easily inserted in the interstitial sites of early transition metals with negligible change to the crystal, which significantly improve the d-band structure.T hese changes can narrow the Fermi-level gap of transition metals compared with noble metals,l eading to improved catalytic performance. [59] Furthermore,b onding of nitrogen with less electronegative elements (e.g.t ransition metals) leads to charge transfer in the resulting nitrides.T his charge transfer activates the surface by producing acidic/basic sites for sorption of oxygenated species and modifying the dband electron density,r esulting in improvement of the catalytic response. [60] Several single-metal (TiN,C oN x , Mo x N y ,V N x ,W N x ,A lN) [61][62][63][64][65][66] and multi-metallic (Co-Mo, Co-W) [67,68] nitrides were designed and synthesized to improve the ORR performance.T he potential electrocatalytic application of MN x as an electrode in redox systems was identified for the first time by using TiNa samodel in the basic electrolyte.…”

Section: Metal Nitridesmentioning

confidence: 99%

Earth‐Abundant Nanomaterials for Oxygen Reduction

et al. 2015

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Replacing the rare and precious platinum (Pt) electrocatalysts with earth-abundant materials for promoting the oxygen reduction reaction (ORR) at the cathode of fuel cells is of great interest in developing high-performance sustainable energy devices. However, the challenging issues associated with non-Pt materials are still their low intrinsic catalytic activity, limited active sites, and the poor mass transport properties. Recent advances in material sciences and nanotechnology enable rational design of new earth-abundant materials with optimized composition and fine nanostructure, providing new opportunities for enhancing ORR performance at the molecular level. This Review highlights recent breakthroughs in engineering nanocatalysts based on the earth-abundant materials for boosting ORR.

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Section: Metal Nitridesmentioning

confidence: 99%

Earth‐Abundant Nanomaterials for Oxygen Reduction

et al. 2015

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“…Diese Veränderungen kçnnen die Lücke am Fermi-Niveau der Übergangsmetalle verglichen mit Edelmetallen verengen, was zu der besseren katalytischen Leistung führt. [59] Darüber hinaus führt die Bindung von Stickstoff an weniger elektronegative Elemente (z. B. Übergangsmetalle) zu einem Ladungstransfer in die resultierenden Nitride.D ieser Ladungstransfer aktiviert die Oberfläche,i ndem er saure/basische Zentren für die Sorption der oxygenierten Spezies schafft und die Elektronendichte im d-Band modifiziert, was zu einer Verbesserung der katalytischen Aktivität führt.…”

Section: Metallnitrideunclassified

Platinfreie Nanomaterialien für die Sauerstoffreduktion

et al. 2015

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Der Ersatz von Platin (Pt) durch billigere, unedle Elemente in Elektrokatalysatoren für die Sauerstoffreduktionsreaktion (ORR) ist für die Entwicklung nachhaltiger, leistungsfähiger Brennstoffzellen zur Energieumwandlung von größtem Interesse. Platinfreie Materialien bergen jedoch eine Reihe von Herausforderungen, wie eine geringe intrinsische katalytische Aktivität, eine begrenzte Zahl aktiver Zentren und schlechte Stofftransporteigenschaften. Jüngste Fortschritte in den Materialwissenschaften und der Nanotechnologie ermöglichen nun ein rationales Design von neuen Materialien mit unedlen Elementen mit optimierter Zusammensetzung und präziser Nanostruktur. Dies eröffnet neue Möglichkeiten zur Verbesserung der ORR‐Leistung auf molekularer Ebene. Dieser Aufsatz beleuchtet die aktuellen Durchbrüche bei der Entwicklung von Nanokatalysatoren für die ORR.

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“…The carbides of Groups IV-VI, in particular, exhibit catalytic properties akin to platinum-group metals. Indeed, there have been several attempts to utilize tungsten carbide (WC) as an electro-catalyst because of its platinum-like catalytic behavior, its stability in acid solutions at anodic potentials, and its resistance to CO poisoning [12]. But when used as an anodic material in a DMFC, pristine WC exhibits low electrocatalytic activity albeit its resistance to CO poisoning [13].…”

Section: Introductionmentioning

confidence: 99%

Durable Transition‐Metal‐Carbide‐Supported Pt–Ru Anodes for Direct Methanol Fuel Cells

et al. 2012

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Molybdenum carbide (MoC) and tungsten carbide (WC) are synthesized by direct carbonization method. Pt–Ru catalysts supported on MoC, WC, and Vulcan XC‐72R are prepared, and characterized by X‐ray diffraction, X‐ray photoelectron spectroscopy, and transmission electron microscopy in conjunction with electrochemistry. Electrochemical activities for the catalysts towards methanol electro‐oxidation are studied by cyclic voltammetry. All the electro‐catalysts are subjected to accelerated durability test (ADT). The electrochemical activity of carbide‐supported electro‐catalysts towards methanol electro‐oxidation is found to be higher than carbon‐supported catalysts before and after ADT. The study suggests that Pt–Ru/MoC and Pt–Ru/WC catalysts are more durable than Pt–Ru/C. Direct methanol fuel cells (DMFCs) with Pt–Ru/MoC and Pt–Ru/WC anodes also exhibit higher performance than the DMFC with Pt–Ru/C anode.

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Transition Metal Carbides and Nitrides as Electrode Materials for Low Temperature Fuel Cells

Cited by 398 publications

References 112 publications

Earth‐Abundant Nanomaterials for Oxygen Reduction

Earth‐Abundant Nanomaterials for Oxygen Reduction

Platinfreie Nanomaterialien für die Sauerstoffreduktion

Durable Transition‐Metal‐Carbide‐Supported Pt–Ru Anodes for Direct Methanol Fuel Cells

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