Metal−Organic Framework‐Derived Nitrogen‐Doped Core‐Shell‐Structured Porous Fe/Fe<sub>3</sub>C@C Nanoboxes Supported on Graphene Sheets for Efficient Oxygen Reduction Reactions

Hou, Yang; Huang, Taizhong; Wen, Zhenhai; Mao, Shun; Cui, Shumao; Chen, Junhong

doi:10.1002/aenm.201400337

Cited by 519 publications

(330 citation statements)

References 68 publications

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“…However, they generally suffer from a large overpotential of 1.5 V and low round-trip efficiency (53%-64 %). Heteroatom doping or hybridization with metal species represents an efficient way to enhance the activity of carbon-based catalysts towards oxygen reduction reaction (ORR)/OER reactions [39][40][41][42]. The presence of heteroatoms (e.g., N) and metal species not only reduces the local work function on carbon surface for better O2 adsorption, but also changes the charge density on the carbon surface via electron transfer effect [16,[43][44][45][46][47][48][49][50][51].…”

Section: Introductionmentioning

confidence: 99%

Long life rechargeable Li-O2 batteries enabled by enhanced charge transfer in nanocable-like Fe@N-doped carbon nanotube catalyst

Zhou

Liu

et al. 2017

Sci. China Mater.

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Rechargeable Li-O2 batteries have attracted considerable interests because of their exceptional energy density. However, the short lifetime still remained as one of the bottle-neck obstacles for the practical application of rechargeable Li-O2 batteries. The development of efficient cathode catalyst is highly desirable to reduce the energy barrier of Li-O2 reaction and electrode failure. In this work, we report a facile strategy for the fabrication of a high-performance cathode catalyst for rechargeable Li-O2 batteries by the encapsulation of high content of active Fe nanorods into N-doped carbon nanotubes with high stability (denoted as Fe@NCNTs). First-principles calculations reveal that the synergistic charge transfer and redistribution between the interface of Fe nanorods, the CNT walls and the active N dopants greatly facilitate the chemisorption and subsequent dissociation of O2 molecules into the epoxy intermediates on the carbon surface, which benefits the uniform growth of nanosized discharge products on CNT surface and thus boosts the reversibility of Li-O2 reactions. As a result, the cathode with Fe@NCNT catalyst exhibits long cycling stability with high capacities (1000 mA h g −1 for 160 cycles and 600 mA h g −1 for 270 cycles). Based on the total mass of Fe@NCNTs + Li2O2, high gravimetric energy densities of 2120-2600 W h kg −1 can be achieved at the power densities of 50-795 W kg −1 .

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Section: Introductionmentioning

confidence: 99%

Long life rechargeable Li-O2 batteries enabled by enhanced charge transfer in nanocable-like Fe@N-doped carbon nanotube catalyst

Zhou

Liu

et al. 2017

Sci. China Mater.

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“…In addition to Co-based MOFs, other transition metal-based MOFs, like Fe-based MOFs, have also been reported as precursors in the fabrication of Fe-Nx-C and N-doped Fe/Fe 3 C@C/RGO catalysts to activate ORR in alkaline media [17,[59][60][61]66]. Tang and co-workers [17] can be employed to develop Fe-Nx-C nanostructure as an electrocatalyst (Figure 9).…”

Section: Mof-derived Iron/iron Oxide-nanocarbon Electrocatalystsmentioning

confidence: 99%

“…Additionally, the porosity structure derived from the MOFs particles could promote diffusion of both reactants (O 2 ) and products (OH´), which promises the limiting current density of Fe-Nx-C catalyst is considerably 1.2 times higher than that of Pt/C. using GO as a conductive support and Prussian blue (PB-created from assembly of iron components with N-containing polyvinylpyrrolidone) nanocubes as carbon precursors [61]. During pyrolysis, the continuous decomposition of PB precursor was accompanied by the production of nitrogencontaining gases, resulting in the formation of a PB-nanocarbon with porous and N-doped structure.…”

Section: Mof-derived Iron/iron Oxide-nanocarbon Electrocatalystsmentioning

confidence: 99%

Recent Progress on MOF-Derived Nanomaterials as Advanced Electrocatalysts in Fuel Cells

et al. 2016

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Developing a low cost, highly active and durable cathode material is a high-priority research direction toward the commercialization of low-temperature fuel cells. However, the high cost and low stability of useable materials remain a considerable challenge for the widespread adoption of fuel cell energy conversion devices. The electrochemical performance of fuel cells is still largely hindered by the high loading of noble metal catalyst (Pt/Pt alloy) at the cathode, which is necessary to facilitate the inherently sluggish oxygen reduction reaction (ORR). Under these circumstances, the exploration of alternatives to replace expensive Pt-alloy for constructing highly efficient non-noble metal catalysts has been studied intensively and received great interest. Metal-organic frameworks (MOFs) a novel type of porous crystalline materials, have revealed potential application in the field of clean energy and demonstrated a number of advantages owing to their accessible high surface area, permanent porosity, and abundant metal/organic species. Recently, newly emerging MOFs materials have been used as templates and/or precursors to fabricate porous carbon and related functional nanomaterials, which exhibit excellent catalytic activities toward ORR or oxygen evolution reaction (OER). In this review, recent advances in the use of MOF-derived functional nanomaterials as efficient electrocatalysts in fuel cells are summarized. Particularly, we focus on the rational design and synthesis of highly active and stable porous carbon-based electrocatalysts with various nanostructures by using the advantages of MOFs precursors. Finally, further understanding and development, future trends, and prospects of advanced MOF-derived nanomaterials for more promising applications of clean energy are presented.

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“…4d, the deconvoluted N 1s contains three peaks positioned at 399.2, 400.9 and 402.4 eV, which can be respectively ascribed to pyrrolic N, graphitic N and oxidized N [31] derived from N elements in pyrrole upon heat treatment. Among them, the pyrrolic and graphitic N species can promote the oxygen reduction via changing the chemical/electronic environment of the neighboring carbon atoms [32][33][34]. Besides, a lower binding energy of 398.5 eV may be attributed to the interaction between Pt and N atoms [15,16].…”

Section: Characterization Of As-prepared Catalystsmentioning

confidence: 99%

A facile strategy for ultrasmall Pt NPs being partially-embedded in N-doped carbon nanosheet structure for efficient electrocatalysis

2018

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A facile strategy is established for constructing composite nanostructure with ultrasmall Pt nanoparticles (NPs) of~2 nm in diameter being homogeneously embedded in N-doped carbon nanosheets. The strong coordination between Pt atoms in cisplatin and N atoms in pyrrole contributes to the robust embedding of Pt NP into the N-doped carbon nanosheets after annealing. Such a unique partially-embedding structure facilitates the active site exposure while stabilizing the ultrasmall Pt NPs, leading to the comparable electrochemical activities for hydrogen evolution and oxygen reduction reactions, and substantially improves durability performance compared to that of the state-of-the-art Pt/C (20 wt%).

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Metal−Organic Framework‐Derived Nitrogen‐Doped Core‐Shell‐Structured Porous Fe/Fe₃C@C Nanoboxes Supported on Graphene Sheets for Efficient Oxygen Reduction Reactions

Cited by 519 publications

References 68 publications

Long life rechargeable Li-O2 batteries enabled by enhanced charge transfer in nanocable-like Fe@N-doped carbon nanotube catalyst

Long life rechargeable Li-O2 batteries enabled by enhanced charge transfer in nanocable-like Fe@N-doped carbon nanotube catalyst

Recent Progress on MOF-Derived Nanomaterials as Advanced Electrocatalysts in Fuel Cells

A facile strategy for ultrasmall Pt NPs being partially-embedded in N-doped carbon nanosheet structure for efficient electrocatalysis

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Metal−Organic Framework‐Derived Nitrogen‐Doped Core‐Shell‐Structured Porous Fe/Fe3C@C Nanoboxes Supported on Graphene Sheets for Efficient Oxygen Reduction Reactions

Cited by 519 publications

References 68 publications

Long life rechargeable Li-O2 batteries enabled by enhanced charge transfer in nanocable-like Fe@N-doped carbon nanotube catalyst

Long life rechargeable Li-O2 batteries enabled by enhanced charge transfer in nanocable-like Fe@N-doped carbon nanotube catalyst

Recent Progress on MOF-Derived Nanomaterials as Advanced Electrocatalysts in Fuel Cells

A facile strategy for ultrasmall Pt NPs being partially-embedded in N-doped carbon nanosheet structure for efficient electrocatalysis

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Metal−Organic Framework‐Derived Nitrogen‐Doped Core‐Shell‐Structured Porous Fe/Fe₃C@C Nanoboxes Supported on Graphene Sheets for Efficient Oxygen Reduction Reactions