Ternary PtIrNi Catalysts for Efficient Electrochemical Ammonia Oxidation

Ternary PtIrNi Catalysts for Efficient Electrochemical Ammonia Oxidation

Ammonia (NH3) has proved to be an effective alternative to hydrogen in low-temperature fuel cells via its direct ammonia oxidation reaction (AOR). However, the kinetically sluggish AOR has prohibitively hindered the attractive direct ammonia fuel cell (DAFC) applications. Here, we report an efficien...

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Bibliographic Details
Published in:ACS catalysis Vol. 10; no. 7; pp. 3945 - 3957
Main Authors: Li, Yi, Li, Xing, Pillai, Hemanth Somarajan, Lattimer, Judith, Mohd Adli, Nadia, Karakalos, Stavros, Chen, Mengjie, Guo, Lin, Xu, Hui, Yang, Juan, Su, Dong, Xin, Hongliang, Wu, Gang
Format: Journal Article
Language:English
Published: United States American Chemical Society 03-04-2020
American Chemical Society (ACS)
Subjects:
ammonia oxidation reaction
DFT calculations
direct ammonia fuel cells
Electrocatalysis
ENERGY STORAGE
PtIrNi ternary alloy
PtIrNi ternary alloy
electrocatalysis
direct ammonia fuel cells
ammonia oxidation reaction
DFT calculations
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Summary:Ammonia (NH3) has proved to be an effective alternative to hydrogen in low-temperature fuel cells via its direct ammonia oxidation reaction (AOR). However, the kinetically sluggish AOR has prohibitively hindered the attractive direct ammonia fuel cell (DAFC) applications. Here, we report an efficient AOR catalyst, in which ternary PtIrNi alloy nanoparticles well dispersed on a binary composite support consisting of porous silicon dioxide (SiO2) and carboxyl-functionalized carbon nanotube (PtIrNi/SiO2-CNT-COOH) through a sonochemical-assisted synthesis method. The PtIrNi alloy nanoparticles, with the aid of abundant OHad provided by porous SiO2 and the improved electrical conductivity by CNTs, exhibit remarkable catalytic activity for the AOR in alkaline media. It is evidenced by a lower onset potential (∼0.40 V vs reversible hydrogen electrode (RHE)) at room temperature than that of commercial PtIr/C (ca. 0.43 V vs RHE). Increasing NH3 concentrations and operation temperatures can significantly enhance AOR activity of this PtIrNi nanoparticle catalyst. Specifically, the catalyst at the temperature of 80 °C exhibits a much lower onset potential (∼0.32 V vs RHE) and a higher peak current density, indicating that DAFCs operated at a higher temperature are favorable for increased performance. Constant-potential density functional theory (DFT) calculations showed that the Pt–Ir ensembles on {100}-terminated surfaces serve as the active site. The introduction of Ni raises the center energy of the density of states projected onto the group d-orbitals of surface sites and thus lowers the theoretical onset potential for *NH2 dehydrogenation to *NH compared to Pt and Pt3Ir alloy.
Bibliography:BNL-213739-2020-JAAM
USDOE Advanced Research Projects Agency - Energy (ARPA-E)
SC0012704
ISSN:2155-5435
2155-5435
DOI:10.1021/acscatal.9b04670