Effect of local pH change on non-PGM catalysts - a potential-dependent mechanistic analysis of the oxygen reduction reaction

Typically, the ORR shows higher activity in alkaline electrolytes than in acidic media on either platinum-group metal (PGM) or non-PGM catalysts, known from their outer sphere electron transfer (OSET) mechanism via adsorbed hydroxyl species on the platinum-carbon electrode. However, poor understandi...

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Bibliographic Details
Published in:Catalysis science & technology 2022-10, Vol.12 (2), p.6246-6255
Main Authors: Anjana, J, Muthukrishnan, Azhagumuthu
Format: Article
Language:English
Subjects:
Catalysts
Chemical reduction
Electrolytes
Electron transfer
Hydrogen peroxide
Oxygen reduction reactions
Platinum metals
Polypyrroles
Potassium perchlorates
Ring currents
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Summary:Typically, the ORR shows higher activity in alkaline electrolytes than in acidic media on either platinum-group metal (PGM) or non-PGM catalysts, known from their outer sphere electron transfer (OSET) mechanism via adsorbed hydroxyl species on the platinum-carbon electrode. However, poor understanding of non-PGM catalysts' active sites and the electrical double-layer structure impede the deciphering of the ORR mechanism in alkaline and neutral electrolytes. The ORR on Fe/PPy-900 (synthesized from an Fe-polypyrrole composite) for a full pH range of electrolytes (prepared from HClO 4 , KClO 4 and KOH) was studied using RRDE voltammetry. The ORR mechanism in intermediate pH electrolytes (5 < pH < 11) is elusive due to the concomitant rise in the surface (local) pH with applied potential. The quantitative estimation of potential-dependent local pH by leveraging the RRDE technique elucidates the electrical double layer structure followed by the ORR mechanism in intermediate pH electrolytes. The OSET mechanism operates in the intermediate pH electrolyte for the first 2-electron transfer, followed by the ISET mechanism for the subsequent reduction of adsorbed HO 2 − ions. The smaller ring current in intermediate pH electrolytes can be rationalised by the kinetic facility of the H 2 O 2 reduction reaction. The increasing ring current in the electrolytes having a pH value above 11 is attributed to the inhibition of HO 2 − binding on the active sites due to the active sites being blocked by OH − ions. The increasing ring current with pH (in the alkaline region) supports the above prediction of ISET via the chemisorbed HO 2 − intermediate. The potential-dependent mechanistic transformation of the oxygen reduction reaction originates from the local pH change.
ISSN:2044-4753
2044-4761
DOI:10.1039/d2cy01099b