Mechanism of biomass activation and ammonia modification for nitrogen-doped porous carbon materials

[Display omitted] •The nitrogen-doped porous activated carbons are prepared.•Interaction effects between biomass activation and NH3 modification.•KOH + K2CO3 achieves greener production and better activated carbon structure.•The electrochemical properties of bamboo activated carbons were investigate...

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Bibliographic Details
Published in:Bioresource technology 2019-05, Vol.280, p.260-268
Main Authors: Li, Kaixu, Chen, Wei, Yang, Haiping, Chen, Yingquan, Xia, Sunwen, Xia, Mingwei, Tu, Xin, Chen, Hanping
Format: Article
Language:English
Subjects:
ammonia
bamboos
biomass
Biomass activation
capacitance
carbon
micropores
NH3 modification
nitrogen
nitrogen content
Nitrogen-doped
Porosity
pyrolysis
Supercapacitors
surface area
technology
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Summary:[Display omitted] •The nitrogen-doped porous activated carbons are prepared.•Interaction effects between biomass activation and NH3 modification.•KOH + K2CO3 achieves greener production and better activated carbon structure.•The electrochemical properties of bamboo activated carbons were investigated. The effect of chemical activation and NH3 modification on activated carbons (ACs) was explored via two contrasting bamboo pyrolysis strategies involving either two steps (activation followed by nitrogen doping in NH3 atmosphere) or one step (activation in NH3 atmosphere) with several chemical activating reagents (KOH, K2CO3, and KOH + K2CO3). The ACs produced by the two-step method showed relatively smaller specific surface areas (∼90% micropores) and lower nitrogen contents. From the one-step method, the ACs had larger pore diameters with about 90% small mesopores (2–3.5 nm). Due to a promotion effect with the KOH + K2CO3 combination, the AC attained the greatest surface area (2417 m2 g−1) and highest nitrogen content (3.89 wt%), endowing the highest capacitance (175 F g−1). The balance between surface area and nitrogen content recommends KOH + K2CO3 activation via the one-step method as the best choice for achieving both greener production process and better pore structure.
ISSN:0960-8524
1873-2976
DOI:10.1016/j.biortech.2019.02.039