High-content graphitized N-doped carbon encapsulated Cu catalyst in aqueous phase reforming of methanol for efficient hydrogen production

[Display omitted] •The high content of graphited N-doped carbon encapsulated Cu0/Cu+ catalyst.•In-situ reduction of Cu in low temperature APRM.•Excellent catalytic hydrogen production rate of 46.15 μmol·gcat-1·s−1 at 190 °C. The development of a highly efficient non-noble catalyst for rapid releasin...

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Bibliographic Details
Published in:Fuel (Guildford) 2024-09, Vol.371, p.131888, Article 131888
Main Authors: Chen, Baozhu, Zheng, Zefeng, Hu, Changsong, Zengcai, Ziyu, Liu, Zhonghai, Lu, Minglei, Meng, Qingwei, Wang, Tiejun
Format: Article
Language:English
Subjects:
Aqueous phase reforming
Cu–N synergistic effect
High content of graphitized N-doped
Reduced state copper
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Summary:[Display omitted] •The high content of graphited N-doped carbon encapsulated Cu0/Cu+ catalyst.•In-situ reduction of Cu in low temperature APRM.•Excellent catalytic hydrogen production rate of 46.15 μmol·gcat-1·s−1 at 190 °C. The development of a highly efficient non-noble catalyst for rapid releasing of hydrogen from methanol/water at low temperature is urgent, but challenge. In this paper, the high content of graphited N-doped carbon encapsulated reducing state copper catalyst was fabricated for low-temperature aqueous reforming of methanol. The Cu@NGC-600 catalyst gives excellent hydrogen production rate of 46.15 μmol·gcat-1·s-1 at 190 °C, which is 4 times higher than the commercial 20 % Pt/C catalyst and 3 times higher than other reported Cu-based catalysts (such as the Cu@NC-200 catalyst). Characterization and DFT calculation results revealed that rich doping of graphite N and the synergistic effect of Cu–N strengthened the electron transfer between copper and the NC matrix, decrease the reduction temperature of catalyst, which enabled the Cu to maintain a highly reduced state of Cu0/Cu+ during APRM for low temperature (150–190 °C) hydrogen production.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2024.131888