Effects of carboxylate stabilizers on the structure and activity of carbon-supported Pt–Cu nanoparticles towards methanol oxidation

Effects of carboxylate stabilizers on the structure and activity of carbon-supported Pt–Cu nanoparticles towards methanol oxidation

Carbon-supported Pt–Cu nanoparticles were prepared by alcohol reduction method in the presence of carboxylate stabilizers with different molecular structure (malonate, succinate, adipate, and citrate). The longer was the carbon chain of stabilizer, the smaller dispersed Pt–Cu alloy crystallites and...

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Bibliographic Details
Published in:International journal of hydrogen energy Vol. 42; no. 5; pp. 2984 - 2995
Main Authors: Kugai, Junichiro, Okazaki, Tomohisa, Seino, Satoshi, Nakagawa, Takashi, Yamamoto, Takao A., Tanaka, Shingo
Format: Journal Article
Language:English
Published: Elsevier Ltd 02-02-2017
Subjects:
Alcohol reduction
CO stripping
Methanol oxidation
Nanoparticles
Pt–Cu
Stabilizer
Nanoparticles
CO stripping
Alcohol reduction
Stabilizer
Pt–Cu
Methanol oxidation
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Summary:Carbon-supported Pt–Cu nanoparticles were prepared by alcohol reduction method in the presence of carboxylate stabilizers with different molecular structure (malonate, succinate, adipate, and citrate). The longer was the carbon chain of stabilizer, the smaller dispersed Pt–Cu alloy crystallites and fewer aggregates were obtained, which was attributed to steric effect of the molecular backbone to protect fine dispersed crystallites. Dispersed nanoparticles were Pt-rich and aggregates were high-Cu crystallites due to competitive chemisorption of carboxylate and Cu2+ on metal surface in the course of nanoparticle formation. Citrate gave aggregates of several low-Cu alloy crystallites dispersed on carbon support, which was attributed to strong chemisorption of citrate on metal surface via tridentate coordination. The length of molecular backbone of stabilizer mainly affected size and dispersivity of Pt–Cu nanoparticles while the chemisorption strength of stabilizer on metal surface affected the degree of alloying. The Pt–Cu prepared with succinate showed the highest methanol oxidation activity, which was attributed to moderate size and moderate alloying degree leading to a moderate chemisorption strength of reactants and intermediates. •The structure of Pt–Cu nanoparticles depends on molecular structure of stabilizer.•Steric factor of stabilizer affects dispersivity of Pt–Cu nanoparticles.•Chemisorption strength of stabilizer on metal surface affects the degree of alloying.•Pt–Cu prepared with succinate showed the highest activity for methanol oxidation.•The high activity was attributed to moderate chemisorption strength of reactants.
ISSN:0360-3199
1879-3487
DOI:10.1016/j.ijhydene.2016.12.064