The underlying mechanism trade-off between particle proximity effect and low-Pt loading for oxygen reduction and methanol oxidation reaction activity

•Low loading Pt@N-GCs with controllable ipd were prepared by wet chemical reduction.•Trade-off loading and proximity effect of Pt to design bifunctional catalysts.•Optimal low-Pt loading and fit ipd can define ORR pathway and promote activity.•5.0 wt% Pt@N-GC can effectively improve the MOR activity...

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Bibliographic Details
Published in:Electrochimica acta 2023-06, Vol.454, p.142364, Article 142364
Main Authors: Cheng, Jiarun, Lyu, Chaojie, Dong, Gang, Liu, Yongqiang, Hu, Yue, Han, Bin, Geng, Dongsheng, Zhao, Dongjie
Format: Article
Language:English
Subjects:
Catalytic activity
Low-Pt loading
Methanol oxidation reaction
Oxygen reduction reaction
Proximity effect
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Summary:•Low loading Pt@N-GCs with controllable ipd were prepared by wet chemical reduction.•Trade-off loading and proximity effect of Pt to design bifunctional catalysts.•Optimal low-Pt loading and fit ipd can define ORR pathway and promote activity.•5.0 wt% Pt@N-GC can effectively improve the MOR activity and enhance CO tolerance. Highly efficient and stable Pt-based electrocatalysts have broad application prospects in fuel cells, among which, Pt loading accompanied with particle size, interparticle distance (ipd), and interaction with support are identified as key contributors for high activity and selectivity. Herein, we have developed the nitrogen-doped graphite-like carbon sheets supporting low-Pt loading (Pt@N-GC) with uniform size and controllable ipd, and disentangled the main effect of ipd on oxygen reduction reaction (ORR) and methanol oxidation reaction (MOR) activity. The optimal 5.0 wt% low-Pt loading results in more abundant Pt sites and lower ipd, which leads to the higher surface reactivity by proximity effect, and 2e− pathway can be hindered by strongly resorbing and reducing H2O2 to promote 4e− pathway towards ORR. Simultaneously, the 5.0 wt% Pt@N-GC can effectively improve the MOR activity, enhance the adsorption of -OH group under the appropriate ipd, so as to promote the instantaneous oxidation of CO and enhance the tolerance, and accelerate the oxidative dehydrogenation of methanol. Benefiting by the synergistic effect of Pt nanoparticles and N-GC support, all Pt@N-GCs exhibit bifunctional electrocatalytic activity and durability. We believe the gained trade-off of the loading and proximity effect of Pt, and its influence on catalytic activity and selectivity contributes to design more promising low-Pt loading bifunctional catalysts for fuel cell. Pt@N-GC was constructed to disclose the advantages of particle proximity effect and low-Pt loading, and trade-off the beneficial mechanism of both to improve ORR/MOR activity of Pt-based catalysts. [Display omitted]
ISSN:0013-4686
1873-3859
DOI:10.1016/j.electacta.2023.142364