Non-metal Catalysts for Dioxygen Reduction in an Acidic Electrolyte

Matter, Paul H.; Ozkan, Umit S.

doi:10.1007/s10562-006-0067-1

Cited by 262 publications

(267 citation statements)

References 37 publications

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“…The stable structure of nitrogen doped CNTs and the properties of the N-doped CNTs for the dioxygen adsorption and reduction were studied. The results show that the nitrogen doping on the open-edges of carbon nanotubes is the most stable structure, that is consistent with the previous experimental results of Ozkan et al 4,5 To study the dioxygen dissociation, the minimum energy path searching based nudged elastic band (NEB) 11 method was used to calculate the dioxygen dissociation energy barrier. In the following section of this review paper, the detailed method is described.…”

supporting

confidence: 88%

“…3,4 In 2006, Ozkan and coworkers reported that nitrogen-containing nanostructured carbons and nanotubes have promising catalytic activity towards ORR. 5,6 In a 2008 report, Yang et al at Argonne National Laboratory showed that the vertically-aligned CNT arrays, which are functionalized through nitrogen and iron doping by a chemical vapor deposition (CVD) process, can be electrocatalytically active toward ORR. 7 The functionalized CNTs show promise properties as an alternative non-Pt electrocatalyst with a unique nano-architecture and advantageous material properties for the cathode of PEMFC.…”

Section: Introductionmentioning

confidence: 99%

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Dioxygen adsorption and dissociation on nitrogen doped carbon nanotubes from first principles simulation

Zhao¹,

Khosravi²,

Yang³

2011

Carbon Nanotubes - From Research to Applications

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supporting

confidence: 88%

Section: Introductionmentioning

confidence: 99%

Dioxygen adsorption and dissociation on nitrogen doped carbon nanotubes from first principles simulation

Zhao¹,

Khosravi²,

Yang³

2011

Carbon Nanotubes - From Research to Applications

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“…Although the usual reaction that occurs on carbon electrodes is far less than the four-electron reaction (O 2 + 4 H + + 4 e -→ H 2 O), there have been reports that reactions involving more electrons may take place on nitrogen-containing carbon electrodes [2][3][4][5][6]. Analyses of the ORR by a method involving a rotating ring-disk electrode showed that the ORR on CS900-AC proceeds by a 3.5-electron reaction to give about 25% of hydrogen peroxide (Fig.…”

Section: Resultsmentioning

confidence: 99%

High oxygen-reduction activity of silk-derived activated carbon

Iwazaki

Obinata

Sugimoto

et al. 2009

Electrochemistry Communications

115

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Activated carbon prepared from silk fibroin, which is free of metal elements, showed a high catalytic activity for the oxygen-reduction reaction (ORR). The activated carbon had a very high onset potential of E onset = 0.83 V (vs. RHE) in oxygen saturated 0.5 M H 2 SO 4 at 60 °C. The ORR on the activated carbon proceeded by a four-electron process in the high-electrode-potential region; this gradualy decreased to a 3.5-electron reaction below about 0.6 V (vs. RHE). Only about 1 % of nitrogen atoms (mostly quaternary) remained in the activated carbon by heat treatment at up to 1200 °C are responsible for the high catalytic activity. The open circuit voltage of a polymer electrolyte fuel cell using the activated carbon as the cathode and a platinum/carbon black anode under pure oxygen and hydrogen gases, respectively, both at 1 atmosphere, was 0.96 V at 27 °C.

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“…[10][11][12][13][14] In order to decrease the cost of electrocatalysts and eliminate their dependence on noble metals, various non-noble metal catalysts have been explored recently as alternatives to the Pt-based electrocatalysts, which include chalcogenide catalysts, [15][16][17][18][19] transition metal macrocyclic compounds, [20][21][22] transition metallic oxides [23][24][25][26][27] and carbon-based catalysts. [28][29][30][31][32][33][34][35] In particular, carbon-based catalysts doped with the heteroatoms such as nitrogen (N) or boron (B) have been paid much attention and been proposed as typical non-noble metal catalysts for ORR [36][37][38] in alkaline media. Especially, since Gong et al 37 reported the superior activity and stability of nitrogen doped carbon nanotube in alkaline solution, the heteroatom doped carbon materials have been expected to be promising alternative Pt-based catalysts.…”

mentioning

confidence: 99%

Nitrogen-doped carbon xerogel: A novel carbon-based electrocatalyst for oxygen reduction reaction in proton exchange membrane (PEM) fuel cells

Jin

Zhang

Zhong

et al. 2011

Energy Environ. Sci.

173

116

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A low-cost, novel carbon-based electrocatalyst for oxygen reduction reaction (ORR), nitrogen-doped carbon xerogel (N-CX) was synthesized via a sol-gel polymerization method followed by a pyrolysis process. The N-CX catalyst exhibited a high activity for ORR, and a good stability in acid media. A high performance with a maximum power density of 360 mW cm À2 was achieved on a single PEM fuel cell with N-CX as the cathode electrocatalyst.As one of the key materials of PEM fuel cells, the electrocatalyst for oxygen reduction reaction (ORR) in particular plays a critical role in determining cell performance, cost and durability. The platinumbased carbon-supported electrocatalysts (e.g. Pt/C) have been considered as the most effective elecrocatalysts for ORR in PEM fuel cells due to their high activities and good stabilities. 1-9 However, the issues of high cost, scarce sources and long-term durability limit their large-scale production and hinder the commercialization of PEM fuel cells. [10][11][12][13][14] In order to decrease the cost of electrocatalysts and eliminate their dependence on noble metals, various non-noble metal catalysts have been explored recently as alternatives to the Pt-based electrocatalysts, which include chalcogenide catalysts, 15-19 transition metal macrocyclic compounds, 20-22 transition metallic oxides 23-27 and carbon-based catalysts. [28][29][30][31][32][33][34][35] In particular, carbon-based catalysts doped with the heteroatoms such as nitrogen (N) or boron (B) have been paid much attention and been proposed as typical non-noble metal catalysts for ORR 36-38 in alkaline media. Especially, since Gong et al. 37 reported the superior activity and stability of nitrogen doped carbon nanotube in alkaline solution, the heteroatom doped carbon materials have been expected to be promising alternative Pt-based catalysts. The doped carbon-based catalysts demonstrate tailored physico-chemical properties, such as structure, electrical conductivity, surface properties and oxidation stability, depending on the amount of the incorporated heteroatoms. It is also reported that the incorporated heteroatoms in the carbon structure contribute to the catalytic activities for many reactions 39-41 including the ORR in alkaline media. However, the activities and stabilities of these catalysts in acidic media are still challenging.Recently, carbon xerogels have been reported as the electrode materials for capacitors and electrocatalyst supports because of their controllable structures, high electronic conductivities, good anticorrosion properties, facile preparations and low costs. 42-51 However, they are almost inactive towards the ORR in PEM fuel cells. In this paper, a nitrogen-doped carbon xerogel (N-CX) was developed by incorporating nitrogen into the carbon xerogel and employed as an electrocatalyst for ORR in PEM fuel cells. Broader contextDue to their advantages such as fast response, high efficiency, environmental friendliness, etc., PEM fuel cells are considered as the most promising power sources for t...

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Non-metal Catalysts for Dioxygen Reduction in an Acidic Electrolyte

Cited by 262 publications

References 37 publications

Dioxygen adsorption and dissociation on nitrogen doped carbon nanotubes from first principles simulation

Dioxygen adsorption and dissociation on nitrogen doped carbon nanotubes from first principles simulation

High oxygen-reduction activity of silk-derived activated carbon

Nitrogen-doped carbon xerogel: A novel carbon-based electrocatalyst for oxygen reduction reaction in proton exchange membrane (PEM) fuel cells

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