Engineering PtRu bimetallic nanoparticles with adjustable alloying degree for methanol electrooxidation: Enhanced catalytic performance

Engineering PtRu bimetallic nanoparticles with adjustable alloying degree for methanol electrooxidation: Enhanced catalytic performance

[Display omitted] •PtRu/PC–H nanocatalyst with a higher alloying degree has been prepared via thermal treatment method.•Electrocatalytic performance for MOR could be dramatically enhanced through high temperature annealing.•In-situ FTIR spectra, methanol molecules can be electrooxidized into CO2 at...

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Bibliographic Details
Published in:Applied catalysis. B, Environmental Vol. 263; p. 118345
Main Authors: Zhang, Junming, Qu, Ximing, Han, Yu, Shen, Linfan, Yin, Shuhu, Li, Guang, Jiang, Yanxia, Sun, Shigang
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 01-04-2020
Elsevier BV
Subjects:
Alloying
Anode effect
Bimetals
Carbon dioxide
Catalysts
Electrochemistry
Fuel cells
Fuel technology
Heat treatment
High temperature
Hydrogen bonds
In-situ FTIRS
Intermetallic compounds
Maximum power density
Methanol
Methanol oxidation
Nanoalloys
Nanoparticles
Poisoning
Porous graphitic carbon
PtRu alloy
Ruthenium
Synergistic effect
Thermal treatment
PtRu alloy
In-situ FTIRS
Porous graphitic carbon
Methanol oxidation
Thermal treatment
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Summary:[Display omitted] •PtRu/PC–H nanocatalyst with a higher alloying degree has been prepared via thermal treatment method.•Electrocatalytic performance for MOR could be dramatically enhanced through high temperature annealing.•In-situ FTIR spectra, methanol molecules can be electrooxidized into CO2 at a lower potential for PtRu/PC–H nanoalloy.•PtRu/PC–H nanocatalyst exhibits maximum power density of 83.7 mW cm−2 in single methanol fuel cell test. PtRu bimetal is of particularly attractive in various electrocatalytic reactions owing to its synergistic effect, ligand effect and strain effect. Here, PtRu nanoalloy supported on porous graphitic carbon (PC) has been successfully prepared via a very facile method involving co-reduction the precursors of Pt and Ru at 300 °C by H2 (PtRu/PCL) followed by thermal treatment at high temperature (700 °C, PtRu/PC–H). Specifically, the electrocatalytic performance of PtRu/PC nanoalloy could be dramatically enhanced through high-temperature annealing. This strategy has synthesized smaller Pt and PtRu nanoparticles (ca. < 3 nm); what's more, they are all homogeneous deposited on the surface of PC. PtRu/PC–H nanocatalyst displays higher alloying degree and stronger electronic interaction between Pt and Ru atoms accompanied by the downshift of Pt d-band center. Studies of electrochemical tests indicate that the as-fabricated PtRu/PC–H sample exhibits superior electrocatalytic performance and excellent CO-poisoning tolerance compared with PtRu/PCL and Pt/PC nanocatalysts. The mass activity and specific activity on PtRu/PC–H nanoalloy can be increased to 1674.2 mA mg−1Pt and 4.4 mA cm−2 for MOR, it is 4.08 and 8.80 times higher than that of the Pt/PC nanocatalyst, respectively. From in-situ FTIR spectra, we can discover PtRu/PC–H nanoalloy generates CO2 at a lower potential of −150 mV than those on PtRu/PC–L (0 mV) and Pt/PC (50 mV) nanocatalysts, dramatically improves the ability of cleavage C–H bond and alleviates the COads poisoning on active sites. The PtRu/PCH nanocatalyst exhibits maximum power density of 83.7 mW cm−2 in single methanol fuel cell test, which more than threefold than that of commercial Pt/C as the anode catalyst. Those experimental results open an effective and clean avenue in the development and preparation of high-performance Pt-based nanocatalysts for direct methanol fuel cells.
ISSN:0926-3373
1873-3883
DOI:10.1016/j.apcatb.2019.118345