Iron‐Free Cathode Catalysts for Proton‐Exchange‐Membrane Fuel Cells: Cobalt Catalysts and the Peroxide Mitigation Approach

Wang, Xiao Xia; Prabhakaran, Venkateshkumar; He, Yanghua; Shao, Yuyan; Wu, Gang

doi:10.1002/adma.201805126

Cited by 220 publications

(155 citation statements)

References 118 publications

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“…This traditional synthesis concept has primarily limited the improvement of catalyst performance due to poor control of the catalyst morphology and the local structure of the active sites. Because of the complex synthesis procedures, the nature of such MN 4 active sites and their formation mechanisms have remained elusive for several decades …”

Section: Introductionmentioning

confidence: 99%

Thermally Driven Structure and Performance Evolution of Atomically Dispersed FeN₄ Sites for Oxygen Reduction

et al. 2019

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FeN4 moieties embedded in partially graphitized carbon are the most efficient platinum group metal free active sites for the oxygen reduction reaction in acidic proton‐exchange membrane fuel cells. However, their formation mechanisms have remained elusive for decades because the Fe−N bond formation process always convolutes with uncontrolled carbonization and nitrogen doping during high‐temperature treatment. Here, we elucidate the FeN4 site formation mechanisms through hosting Fe ions into a nitrogen‐doped carbon followed by a controlled thermal activation. Among the studied hosts, the ZIF‐8‐derived nitrogen‐doped carbon is an ideal model with well‐defined nitrogen doping and porosity. This approach is able to deconvolute Fe−N bond formation from complex carbonization and nitrogen doping, which correlates Fe−N bond properties with the activity and stability of FeN4 sites as a function of the thermal activation temperature.

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Section: Introductionmentioning

confidence: 99%

Thermally Driven Structure and Performance Evolution of Atomically Dispersed FeN₄ Sites for Oxygen Reduction

et al. 2019

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“…Although Fe-N-C catalysts possess the highest activity of the transition metal catalysts, Fe ions are known to catalyze the formation of hydroperoxyl radical oxygen species (ROS) via the Fenton reactions when they meet H 2 O 2 , an unwanted byproduct of the ORR process. [49,50] The as-generated ROS further destroys the local carbon structure and MN 4 sites in the catalysts. Even worse, it attacks the ionomer and membrane in PEMFCs, thereby causing severe failure of MEAs.…”

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confidence: 99%

Single Cobalt Sites Dispersed in Hierarchically Porous Nanofiber Networks for Durable and High‐Power PGM‐Free Cathodes in Fuel Cells

et al. 2020

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Atomically dispersed and nitrogencoordinated single metal sites embedded in carbon (denoted as M-N-C) have emerged as promising platinum-groupmetal-free (PGM-free) catalysts for the oxygen reduction reaction (ORR) cathode in proton-exchange-membrane fuel cells (PEMFCs). [1-5] The MN 4 (M: Fe, Co, or Mn) moieties have been theoretically predicted and then experimentally verified as the active sites in M-N-C catalysts. [6-13] Among the many studied precursors, zinc-based zeolitic imidazolate frameworks (ZIF-8s) are effective in creating atomically dispersed MN 4 sites embedded in defect-rich carbon during the hightemperature carbonization. [8,10,14-17] Despite their encouraging ORR activity demonstrated in aqueous acidic electrolytes recently, [18] the trend is often difficult to reproduce in the membrane electrode assemblies (MEAs) of PEMFCs using solid-state electrolytes (i.e., Nafion) (Table S1, Supporting Information). [19] Low catalyst utilization, severe carbon corrosion, and inferior mass transport within the Increasing catalytic activity and durability of atomically dispersed metalnitrogen-carbon (M-N-C) catalysts for the oxygen reduction reaction (ORR) cathode in proton-exchange-membrane fuel cells remains a grand challenge. Here, a high-power and durable CoN -C nanofiber catalyst synthesized through electrospinning cobalt-doped zeolitic imidazolate frameworks into selected polyacrylonitrile and poly(vinylpyrrolidone) polymers is reported. The distinct porous fibrous morphology and hierarchical structures play a vital role in boosting electrode performance by exposing more accessible active sites, providing facile electron conductivity, and facilitating the mass transport of reactant. The enhanced intrinsic activity is attributed to the extra graphitic N dopants surrounding the CoN 4 moieties. The highly graphitized carbon matrix in the catalyst is beneficial for enhancing the carbon corrosion resistance, thereby promoting catalyst stability. The unique nanoscale X-ray computed tomography verifies the well-distributed ionomer coverage throughout the fibrous carbon network in the catalyst. The membrane electrode assembly achieves a power density of 0.40 W cm −2 in a practical H 2 /air cell (1.0 bar) and demonstrates significantly enhanced durability under accelerated stability tests. The combination of the intrinsic activity and stability of single Co sites, along with unique catalyst architecture, provide new insight into designing efficient PGM-free electrodes with improved performance and durability.

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“…In cases when the catalyst distribution is heterogeneous and dynamic, in situ spatially resolved techniques may be required. Characterization of the ORR performance is further complicated by the generation of reactive oxygen species (ROSs), namely, hydroxyl and hydroperoxyl radicals formed by decomposition of the hydrogen peroxide (H 2 O 2 ) intermediate on the carbon support of the Pt catalysts (Trogadas et al, 2011;Wang et al, 2019;Trogadas and Coppens, 2020). ROSs attack the polymer binding holding the catalysts to the electrode, resulting in substantial particle aggregation and variation in edge-toedge distances between particles.…”

Section: Introductionmentioning

confidence: 99%

“…Perhaps the most active PGM-free ORR catalysts are ligated iron species formed by sintering of organometallic precursors with argon or nitrogen (Lefèvre et al, 2009;Sun et al, 2017;Zhang et al, 2017;Li et al, 2019). Unfortunately, leached iron from ligated iron catalysts promotes decomposition of intermediate hydrogen peroxide, formed during the ORR, into ROS (Wang et al, 2019;Du et al, 2020). In addition to the deleterious effects of ROS generation, other components of PEFCs are especially sensitive to radical formation.…”

Section: Introductionmentioning

confidence: 99%

“…Specifically, the polymer membrane will degrade in the presence of ROS, eventually forming pinholes that lead to complete cell failure (Mittal et al, 2006;Coms, 2008;Gubler et al, 2011). Substantial ROS generation persists even in iron-free and PGM-free ORR catalysts, emphasizing the importance of this reaction (Wang et al, 2019;Du et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

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Mapping Localized Peroxyl Radical Generation on a PEM Fuel Cell Catalyst Using Integrated Scanning Electrochemical Cell Microspectroscopy

et al. 2020

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Understanding molecular-level transformations resulting from electrochemical reactions is important in designing efficient and reliable energy technologies. In this work, a novel integrated scanning electrochemical cell microspectroscopy (iSECCMS) capability is developed by combining a high spatial resolution electrochemical scanning probe with in situ fluorescence spectroscopy. Using 6-carboxyfluorescein as a fluorescent probe, the iSECCMS platform is employed to measure the effect of the detrimental generation of reactive oxygen species (ROS) formed at the active sites of oxygen reduction reaction (ORR) catalysts. Carbon-supported tantalum-doped titanium oxide (TaTiO x) catalysts, a potential Pt-group-metal-free (PGM-free) cathode material explored for low temperature polymer electrolyte fuel cells (PEFCs), is used as a representative model ORR system, where generation of intermediate H 2 O 2 instead of fully oxidized H 2 O is a major concern. We establish that the iSECCMS platform provides a novel and versatile capability for spatially resolved mapping of in situ ROS generation and activity during the kinetically-limited ORR and may, therefore, aid the future characterization and development of high-performance PGM-free PEFC cathodes.

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Iron‐Free Cathode Catalysts for Proton‐Exchange‐Membrane Fuel Cells: Cobalt Catalysts and the Peroxide Mitigation Approach

Cited by 220 publications

References 118 publications

Thermally Driven Structure and Performance Evolution of Atomically Dispersed FeN₄ Sites for Oxygen Reduction

Thermally Driven Structure and Performance Evolution of Atomically Dispersed FeN₄ Sites for Oxygen Reduction

Single Cobalt Sites Dispersed in Hierarchically Porous Nanofiber Networks for Durable and High‐Power PGM‐Free Cathodes in Fuel Cells

Mapping Localized Peroxyl Radical Generation on a PEM Fuel Cell Catalyst Using Integrated Scanning Electrochemical Cell Microspectroscopy

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Iron‐Free Cathode Catalysts for Proton‐Exchange‐Membrane Fuel Cells: Cobalt Catalysts and the Peroxide Mitigation Approach

Cited by 220 publications

References 118 publications

Thermally Driven Structure and Performance Evolution of Atomically Dispersed FeN4 Sites for Oxygen Reduction

Thermally Driven Structure and Performance Evolution of Atomically Dispersed FeN4 Sites for Oxygen Reduction

Single Cobalt Sites Dispersed in Hierarchically Porous Nanofiber Networks for Durable and High‐Power PGM‐Free Cathodes in Fuel Cells

Mapping Localized Peroxyl Radical Generation on a PEM Fuel Cell Catalyst Using Integrated Scanning Electrochemical Cell Microspectroscopy

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Thermally Driven Structure and Performance Evolution of Atomically Dispersed FeN₄ Sites for Oxygen Reduction

Thermally Driven Structure and Performance Evolution of Atomically Dispersed FeN₄ Sites for Oxygen Reduction