Synthesis of highly active amorphous platinum-based catalysts for methanol electrooxidation
Cleaner, greener energy sources are of increasing demands due to the rapid worsening of the global climate. Fuel cells have long been considered a strong contender due to its promise of high efficiency and low cost. The research community has paid paramount attention to the development of fuel ce...
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Format: | Thesis-Master by Research |
Language: | English |
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Nanyang Technological University
2021
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Online Access: | https://hdl.handle.net/10356/146117 |
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Institution: | Nanyang Technological University |
Language: | English |
Summary: | Cleaner, greener energy sources are of increasing demands due to the rapid worsening
of the global climate. Fuel cells have long been considered a strong contender due to its
promise of high efficiency and low cost. The research community has paid paramount
attention to the development of fuel cells, a significant portion of which is on improving
the catalysts, especially Pt. Among several approaches that have been employed to boost
performance of Pt catalysts, amorphous structure is a promising direction. Amorphous
structure houses a large amount of lattice defects which contains a plethora of
uncoordinated active sites, which have been reported to boost catalytic activity.
However, the most common approach to create amorphous structure by alloying with
transition metals such as Ni has limitations. Firstly, transition metals are unstable in the
working condition of fuel cells. Second, the dissolved metal ions can cause damage to
the Nafion membrane of the fuel cell. Induce amorphous structure using non-metals can
solve these problems. This strategy has been successfully employed on various metals
like Ni, Co, Pd via P-doping.
In this thesis, a facile synthesis of transition metal-free amorphous Pt-P nanocatalyst
via P-doping was developed. Amorphous structure was induced by lattice strains
caused by phosphorus doping at high concentration. The resulting Pt-P nanocatalysts
yielded superior catalytic activity compared to commercial PtRu/C for methanol
oxidation reaction in both alkaline and acidic conditions. It was also more durable in
short-term and long-term chronoamperometry tests than PtRu/C. There is potential of
further applications for the synthesized amorphous Pt-P nanocatalysts. |
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