Electrocatalytic synthesis of ammonia by surface proton hopping

Highly efficient ammonia synthesis at a low temperature is desirable for future energy and material sources. We accomplished efficient electrocatalytic low-temperature ammonia synthesis with the highest yield ever reported. The maximum ammonia synthesis rate was 30 099 μmol g h over a 9.9 wt% Cs/5.0...

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Bibliographic Details
Published in:Chemical science (Cambridge) 2017, Vol.8 (8), p.5434-5439
Main Authors: Manabe, R, Nakatsubo, H, Gondo, A, Murakami, K, Ogo, S, Tsuneki, H, Ikeda, M, Ishikawa, A, Nakai, H, Sekine, Y
Format: Article
Language:English
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Summary:Highly efficient ammonia synthesis at a low temperature is desirable for future energy and material sources. We accomplished efficient electrocatalytic low-temperature ammonia synthesis with the highest yield ever reported. The maximum ammonia synthesis rate was 30 099 μmol g h over a 9.9 wt% Cs/5.0 wt% Ru/SrZrO catalyst, which is a very high rate. Proton hopping on the surface of the heterogeneous catalyst played an important role in the reaction, revealed by IR measurements. Hopping protons activate N even at low temperatures, and they moderate the harsh reaction condition requirements. Application of an electric field to the catalyst resulted in a drastic decrease in the apparent activation energy from 121 kJ mol to 37 kJ mol . N dissociative adsorption is markedly promoted by the application of the electric field, as evidenced by DFT calculations. The process described herein opens the door for small-scale, on-demand ammonia synthesis.
ISSN:2041-6520
2041-6539
DOI:10.1039/c7sc00840f