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            ‐induced thermal treatment significantly influences the development of a high performance low‐platinum core‐shell PtNi/C alloyed oxygen reduction catalyst

Zhao, Qing; Wang, Cheng; Wang, Haifeng; Wang, Jianlong; Tang, Yaping; Mao, Zongqiang; Sasaki, Kazunari

doi:10.1002/er.5265

Cited by 11 publications

(9 citation statements)

References 42 publications

(71 reference statements)

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“…The difference of lattice shrinkage is caused by the alloy formed by Pt and Ni. It will affect the overlapping degree of Pt electron states, causing a downshift of the d-band center that weakens the adsorption strength of the oxygenated intermediate on the surface of the catalyst, which is beneficial for re-exposure of active sites. − …”

Section: Resultsmentioning

confidence: 99%

Metal–Support Interactions in a Molybdenum Oxide Anchored PtNi Alloy for Improving Oxygen Reduction Activity

Feng

Chen

Qian

et al. 2020

ACS Appl. Energy Mater.

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The PtNi alloy exhibits excellent catalytic activity for oxygen reduction. However, particle agglomeration and support corrosion during the electrochemical reaction inevitably decrease its catalytic stability. Herein, we synthesize PtNi anchored on MoO x (PtNi-MoO x /NC) catalysts by pyrolysis treatment and the ethylene glycol method. It exhibits better catalytic stability than the commercial Pt/C and the prepared PtNiMo ternary catalysts. After the 30k cycle accelerated degradation test, the catalytic activity attenuations for PtNi−MoO 3 /NC and PtNi−MoO 2 /NC are 17 and 24%, respectively, which are lower than that of the commercial Pt/C (59%) and the prepared PtNiMo/NC (70%). The stability enhancement can be attributed to the strong metal−support interactions that effectively restrain the aggregation and shedding of PtNi nanoparticles. This work provides a promising strategy to improve the catalytic stability by introducing insoluble metal oxides as support materials for oxygen reduction reaction.

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Section: Resultsmentioning

confidence: 99%

Metal–Support Interactions in a Molybdenum Oxide Anchored PtNi Alloy for Improving Oxygen Reduction Activity

Feng

Chen

Qian

et al. 2020

ACS Appl. Energy Mater.

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“…In addition to the PtNi peak in the XRD pattern of PtNi/C_700 C, a separate peak corresponding to Pt was observed. This was probably due to the segregation ascribed to the difference in the affinity to the supplied gas between the Pt and Ni, or the difference in their bonding strengths, which depended on the type of metal atom during annealing in a hydrogen atmosphere at 700 C. 22 This segregation should be avoided because it may inhibit uniform alloy formation and may also lead to the formation of isolated Pt nanoparticles. Interestingly, no isolated XRD peaks were observed for PtNi@C/C.…”

Section: Preparation Of Carbon Shell-coated Ptni Nanocatalystmentioning

confidence: 99%

“…Interestingly, the Pt content on the surface of the nanoparticles slightly increased, which was probably due to the segregation of Pt during heat treatment in a hydrogen atmosphere. 22 Figure 2F,G are a single high-resolution TEM (HR-TEM) image of a PtNi nanoparticle and its pattern obtained using an inverse FFT process, respectively. The (111) interplanar distance, d-spacing, of the synthesized PtNi nanoparticles was approximately 2.18 Å, which was close to that of the Pt 1 Ni 1 alloy (2.17 Å), confirming the formation of a PtNi alloy with a uniform composition.…”

Section: Preparation Of Carbon Shell-coated Ptni Nanocatalystmentioning

confidence: 99%

Improved platinum‐nickel nanoparticles with dopamine‐derived carbon shells for proton exchange membrane fuel cells

Jang

Lee

Jang

et al. 2022

Intl J of Energy Research

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Using platinum-based alloy nanocatalysts with other transition metals has the advantages of enhancing the oxygen reduction reaction (ORR) activity and reducing the platinum usage. However, there are many challenges to using nanocatalysts, including their instability, which hinder their practical application. In this study, we employed a strategy to improve the intrinsic instability of a nanocatalyst by encapsulating a dopamine-derived carbon layer on the surfaces of nanoparticles. The carbon layer formed on the surfaces of platinum-nickel (PtNi) nanoparticles demonstrated improved stability by inhibiting the nanoparticle growth, even during the heat treatment process. This could induce a high degree of alloying while minimizing the loss of surface area for the nanoparticles, which ensured an improved catalyst activity. Additionally, the PtNi nanocatalyst with the dopamine-derived carbon layer showed an improved performance and stability under long-term fuel cell operation conditions, thus proving the practicality of this strategy. The strategy developed in this study is not only a novel and facile approach to the synthesis of alloy catalysts, but also addresses the inherent instability of nanoparticles, which will encourage the practical use and commercialization of alloy nanocatalysts.

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“…[1][2][3] However, the kinetic limitation of oxygen reduction reaction (ORR) in the cathode, poor long-term stability, high cost and scarcity of platinum based catalysts impede the large-scale industrialization of fuel cells. [4][5][6] In the recent years, investigations on the low cost, highly active and stable non-noble catalysts [7][8][9][10] for fuel cells were comprehensively carried out. According to the earlier reports, 9,[11][12][13][14][15][16][17][18][19] the development of M-N-C (M = transition metals) catalysts was shown to be very promising toward ORR.…”

Section: Introductionmentioning

confidence: 99%

“…With the high energy conversion efficiency and low contaminant emissions, fuel cells play a vital role in the sustainable community 1‐3 . However, the kinetic limitation of oxygen reduction reaction (ORR) in the cathode, poor long‐term stability, high cost and scarcity of platinum based catalysts impede the large‐scale industrialization of fuel cells 4‐6 . In the recent years, investigations on the low cost, highly active and stable non‐noble catalysts 7‐10 for fuel cells were comprehensively carried out.…”

Section: Introductionmentioning

confidence: 99%

Core‐shell FeCo N‐doped biocarbons as stable electrocatalysts for oxygen reduction reaction in fuel cells

Liu

Kuo

2020

Int J Energy Res

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A facile route is described for the synthesis of FeCo alloys encapsulated in the N-doped hierarchical carbon shells (denoted as Fe x Co 100-x @N-doped C) by using a combined hydrothermal carbonization of cellulose and NH 3 microwave ammoxidation. Various spectroscopic measurements are used to characterize the physicochemical properties of Fe x Co 100-x @N-doped C samples and their activity as well as stability in the oxygen reduction reaction (ORR) are investigated in alkaline electrolytes. The Fe x Co 100-x @N-doped C samples exhibit the core FeCo bimetals alloying with N (verified by X-ray absorption spectroscopy [XAS] and transmission electron microscopy) and N-doped onto highly porous carbons in the shell (proofed by N 2 adsorption-desorption isotherms and X-ray photoelectron spectroscopy [XPS]). Among the Fe x Co 100-x @N-doped C catalysts, the Fe 50 Co 50 @N-doped C with an atomic alloy ratio of FeCo (1:1) has a higher ORR performance (E onset = −0.05 V vs Ag/AgCl) and a surpassing durability (via a 4-electron ORR route) in comparison to other Fe x Co 100-x @N-doped C and commercial Pt/C catalysts. By XAS and XPS, the formation of Fe-N in the inner core and pyridinic-N on outer shell may be responsible for the superior ORR performance of Fe 50 Co 50 @Ndoped C catalysts. These biomass-derived carbon composites with unique coreshell FeCoN@N-doped porous carbon structure prepared by using a time and energy saving microwave-assisted method could offer a possible cathodic electrode in fuel cell applications.

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H ₂ ‐induced thermal treatment significantly influences the development of a high performance low‐platinum core‐shell PtNi/C alloyed oxygen reduction catalyst

Cited by 11 publications

References 42 publications

Metal–Support Interactions in a Molybdenum Oxide Anchored PtNi Alloy for Improving Oxygen Reduction Activity

Metal–Support Interactions in a Molybdenum Oxide Anchored PtNi Alloy for Improving Oxygen Reduction Activity

Improved platinum‐nickel nanoparticles with dopamine‐derived carbon shells for proton exchange membrane fuel cells

Core‐shell FeCo N‐doped biocarbons as stable electrocatalysts for oxygen reduction reaction in fuel cells

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H 2 ‐induced thermal treatment significantly influences the development of a high performance low‐platinum core‐shell PtNi/C alloyed oxygen reduction catalyst

Cited by 11 publications

References 42 publications

Metal–Support Interactions in a Molybdenum Oxide Anchored PtNi Alloy for Improving Oxygen Reduction Activity

Metal–Support Interactions in a Molybdenum Oxide Anchored PtNi Alloy for Improving Oxygen Reduction Activity

Improved platinum‐nickel nanoparticles with dopamine‐derived carbon shells for proton exchange membrane fuel cells

Core‐shell FeCo N‐doped biocarbons as stable electrocatalysts for oxygen reduction reaction in fuel cells

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H ₂ ‐induced thermal treatment significantly influences the development of a high performance low‐platinum core‐shell PtNi/C alloyed oxygen reduction catalyst