Plasma-enabled synthesis of ordered PtFe alloy nanoparticles encapsulated with ultrathin N-doped carbon shells for efficient methanol electrooxidation

Methanol oxidation reaction (MOR), the key reaction for clean energy generation in fuel cells, is kinetically sluggish and short-lasting because of insufficient catalytic activity and stability of the common Pt-based electrocatalysts. Ordered Pt alloy structures which promise to surmount these issue...

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Published in:Nano research 2023-02, Vol.16 (2), p.2065-2075
Main Authors: Sun, Xuxu, Mao, Zhijian, Wang, Ruiqi, Pi, Xiaohu, Chen, Changle, Zhong, Junbo, Wang, Qi, Ostrikov, Kostya Ken
Format: Article
Language:English
Subjects:
Atomic/Molecular Structure and Spectra
Biomedicine
Biotechnology
Chemistry and Materials Science
Condensed Matter Physics
Materials Science
Nanotechnology
Research Article
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Summary:Methanol oxidation reaction (MOR), the key reaction for clean energy generation in fuel cells, is kinetically sluggish and short-lasting because of insufficient catalytic activity and stability of the common Pt-based electrocatalysts. Ordered Pt alloy structures which promise to surmount these issues, are challenging and impractical to fabricate using common high-temperature annealing. To address the urgent need for simple and rapid synthesis methods for such alloys, here we report the versatile plasma-assisted thermal annealing synthesis of a robust electrocatalyst with PtFe alloys supported on N-doped carbon nanotubes (denoted as PtFe@NCNT-P). Benefiting from the reactive plasma-specific effects, the PtFe@NCNT-P electrocatalyst features ultrafine PtFe alloy nanoparticles (mean size ∼ 2.88 nm, ordered degree ∼ 87.07%) and ultrathin N-doped carbon (NC) shells (0.3–0.7 nm), leading to the excellent catalytic activity and stability toward MOR. The catalyst shows the specific and mass activities of 3.99 mA/cm 2 and 2,148.5 mA/mg, which are 7.82 and 7.41 times higher than those for commercial Pt/C (0.51 mA/cm 2 , 290 mA/mg), and 2.18 and 2.59 times higher compared to the plasma-untreated PtFe@NCNT (1.83 mA/cm 2 , 829.5 mA/mg), respectively. The PtFe@NCNT-P further exhibits extraordinary stability during the long-term chronoamperometry test and 1,000-cycle cyclic voltammetry scanning, much better compared to PtFe@NCNT samples even after the longer thermal annealing. These findings show great potential of the plasma-enabled synthesis of high-performance carbon-supported metallic electrocatalysts for the emerging clean energy technologies.
ISSN:1998-0124
1998-0000
DOI:10.1007/s12274-022-4890-5