Effect of pyrolysis parameters on the biochar reactivity in the N-absorption reaction of chemical looping ammonia generation

Biochar from slow pyrolysis was applied to Chemical Looping Ammonia Generation (CLAG) to avoid the preparation of ammonia from fossil fuels and relatively expensive H2. The effects of pyrolysis atmosphere, temperature, heating rate, and residence time on the biochar reactivity in the N-adsorption re...

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Bibliographic Details
Published in:Energy (Oxford) 2024-11, Vol.310, p.133321, Article 133321
Main Authors: Liu, Zhongyuan, Yu, Qingbo, Gao, Jinchao, Zhao, Jiatai, Duan, Wenjun
Format: Article
Language:English
Subjects:
Biochar
Chemical looping ammonia generation
Disorder degree
Micropore percentage
Multiple linear regression
Reactivity
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Summary:Biochar from slow pyrolysis was applied to Chemical Looping Ammonia Generation (CLAG) to avoid the preparation of ammonia from fossil fuels and relatively expensive H2. The effects of pyrolysis atmosphere, temperature, heating rate, and residence time on the biochar reactivity in the N-adsorption reaction were investigated. The relationship between specific surface area, average pore diameter, micropore percentage, and disorder degree of biochar on reactivity was evaluated by simple and multiple linear regression and Analysis of Variance (ANOVA). The results showed that the biochar prepared in a CO2 atmosphere with a pyrolysis temperature of 700 °C, a heating rate of 10 °C/min, and a resident time of 30 min had the highest conversion rate of 57.79 % in the N-absorption reaction. When the pyrolysis temperature was increased from 600 °C to 700 °C, the biochar conversion in the N-adsorption reaction was significantly increased due to the Boudouard reaction during biomass pyrolysis. The linear regression and ANOVA results show that the micropore percentage and disorder degree of biochar significantly positively affected the reactivity, guiding feedstock selection and optimization of the preparation method of the carbon source used for CLAG. [Display omitted] •Biochar was a suitable carbon source for application in CLAG.•Increasing the heating rate facilitated the biochar reactivity in a CO2 atmosphere.•The micropore percentage and disorder degree of biochar affected the reactivity.
ISSN:0360-5442
DOI:10.1016/j.energy.2024.133321