Nitrogen‐Doped Porous Carbon Cages for Electrocatalytic Reduction of Oxygen: Enhanced Performance with Iron and Cobalt Dual Metal Centers

Heteroatom‐doped carbon materials are promising electrocatalysts towards the oxygen reduction reaction (ORR). In this study, dual metals (Fe an Co) and nitrogen‐codoped porous carbon cages (CHS−FeCo) were synthesized by controlled pyrolysis of silica nanoparticle‐supported melamine‐formaldehyde resi...

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Published in:ChemCatChem 2020-06, Vol.12 (12), p.3230-3239
Main Authors: Mercado, Rene, Wahl, Carolin, En Lu, Jia, Zhang, Tianjun, Lu, Bingzhang, Zhang, Peng, Lu, Jennifer Q., Allen, A'Lester, Zhang, Jin Z., Chen, Shaowei
Format: Article
Language:English
Subjects:
Cages
Carbon
carbon cage
Cobalt
dual metal
Electrocatalysts
Formaldehyde resins
Iron
Melamine
Nanocomposites
Nanoparticles
Nitrogen
nitrogen-doped
Oxidation resistance
oxygen reduction reaction
Oxygen reduction reactions
Performance enhancement
Photoelectrons
Pyrolysis
silica nanoparticle
Silicon dioxide
X ray photoelectron spectroscopy
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cited_by cdi_FETCH-LOGICAL-c3174-557a390895697e37119eda23327f5a2b7181fbba9d4e455730f9e039889814013
cites cdi_FETCH-LOGICAL-c3174-557a390895697e37119eda23327f5a2b7181fbba9d4e455730f9e039889814013
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container_issue 12
container_start_page 3230
container_title ChemCatChem
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creator Mercado, Rene
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En Lu, Jia
Zhang, Tianjun
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Zhang, Jin Z.
Chen, Shaowei
description Heteroatom‐doped carbon materials are promising electrocatalysts towards the oxygen reduction reaction (ORR). In this study, dual metals (Fe an Co) and nitrogen‐codoped porous carbon cages (CHS−FeCo) were synthesized by controlled pyrolysis of silica nanoparticle‐supported melamine‐formaldehyde resin embedded with iron and cobalt precursors, followed by acid etching. Transmission electron microscopy measurements confirmed the formation of hollow carbon cages, and the absence of metal (oxide) nanoparticles suggested atomic dispersion of the metal species within the mesoporous carbon skeletons. X‐ray photoelectron spectroscopic analysis revealed a composition of mostly carbon, oxygen, and nitrogen, with ca. 1 % metals. Electrochemically, the dual‐metal ones showed a significant enhancement of the catalytic performance towards ORR in alkaline media, as compared to samples with single or no metal dopants. This was accounted for by the synergistic interaction between the Fe and Co centers in the carbon samples, as evidenced in X‐ray absorption spectroscopic studies. Remarkably, the CHS−FeCo sample exhibited apparent resistance against KSCN poisoning, where XPS analysis revealed oxidation of KSCN and no metal‐sulfur interaction, in sharp contrast to the Fe counterpart which was easily poisoned. Results from this study suggest that the synergistic interactions between dual metal centers may be exploited for enhanced ORR performance of carbon‐based nanocomposite catalysts. Together we are better: Dual metals (Fe and Co) and nitrogen‐codoped carbon cages are readily prepared by controlled pyrolysis of silica nanoparticle‐supported melamine‐formaldehyde polymer hybrids that are embedded with Fe and Co salts. Spectroscopic measurements suggest Fe−Co synergistic interactions in the resulting sample, which lead to enhanced electrocatalytic activity towards oxygen reduction reaction, as compared to the metal‐free or monometallic carbon cages.
doi_str_mv 10.1002/cctc.201902324
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Remarkably, the CHS−FeCo sample exhibited apparent resistance against KSCN poisoning, where XPS analysis revealed oxidation of KSCN and no metal‐sulfur interaction, in sharp contrast to the Fe counterpart which was easily poisoned. Results from this study suggest that the synergistic interactions between dual metal centers may be exploited for enhanced ORR performance of carbon‐based nanocomposite catalysts. Together we are better: Dual metals (Fe and Co) and nitrogen‐codoped carbon cages are readily prepared by controlled pyrolysis of silica nanoparticle‐supported melamine‐formaldehyde polymer hybrids that are embedded with Fe and Co salts. 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Remarkably, the CHS−FeCo sample exhibited apparent resistance against KSCN poisoning, where XPS analysis revealed oxidation of KSCN and no metal‐sulfur interaction, in sharp contrast to the Fe counterpart which was easily poisoned. Results from this study suggest that the synergistic interactions between dual metal centers may be exploited for enhanced ORR performance of carbon‐based nanocomposite catalysts. Together we are better: Dual metals (Fe and Co) and nitrogen‐codoped carbon cages are readily prepared by controlled pyrolysis of silica nanoparticle‐supported melamine‐formaldehyde polymer hybrids that are embedded with Fe and Co salts. 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subjects Cages
Carbon
carbon cage
Cobalt
dual metal
Electrocatalysts
Formaldehyde resins
Iron
Melamine
Nanocomposites
Nanoparticles
Nitrogen
nitrogen-doped
Oxidation resistance
oxygen reduction reaction
Oxygen reduction reactions
Performance enhancement
Photoelectrons
Pyrolysis
silica nanoparticle
Silicon dioxide
X ray photoelectron spectroscopy
title Nitrogen‐Doped Porous Carbon Cages for Electrocatalytic Reduction of Oxygen: Enhanced Performance with Iron and Cobalt Dual Metal Centers
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