Effects of Al2O3-based catalysts on bio-oil composition during biomass pyrolysis

•Investigated Al2O3-based supported catalysts' effect on bio-oil in biomass pyrolysis.•Explored Ce, fe and mo as loaded metals and discussed the reaction mechanism.•Al2O3-based supported catalysts reduced phenols and increase aldehydes in bio-oil.•Phenols were reduced by 8.63 %, while aldehydes...

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Published in:Journal of the Taiwan Institute of Chemical Engineers 2024-06, Vol.159, p.105475, Article 105475
Main Authors: Liu, Hongyu, Tang, Yuting, Ma, Xiaoqian, Zhan, Jinbo, Yue, Wenchang
Format: Article
Language:English
Subjects:
Al2O3-based catalysts
Bio-oil
Biomass
Chemical composition
Fast pyrolysis
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Summary:•Investigated Al2O3-based supported catalysts' effect on bio-oil in biomass pyrolysis.•Explored Ce, fe and mo as loaded metals and discussed the reaction mechanism.•Al2O3-based supported catalysts reduced phenols and increase aldehydes in bio-oil.•Phenols were reduced by 8.63 %, while aldehydes increased by 11.06 %.•Provide guidance for the high-value utilization of bio-oil in biomass pyrolysis. Biomass catalytic pyrolysis is one of the effective methods for biomass utilization. Understanding the compound composition changes in bio-oil from biomass pyrolysis with catalysts is crucial for efficient biomass utilization. This study investigated the use of Al2O3-based catalysts with Ce, Fe and Mo as loaded metals for biomass pyrolysis. Detailed analysis was conducted on the influence of Al2O3-based catalysts on bio-oil compound composition during biomass pyrolysis. Furthermore, the reaction mechanism was explored and discussed. The research found that the introduction of Al2O3-based catalysts increased the residual mass during biomass pyrolysis. And addition of loaded metals promoted oxidation–reduction of surface deposits on the catalyst, decreasing residual mass. Through pyrolysis-gas chromatography/mass spectrometry testing, the introduction of Al2O3-based catalysts reduced phenols, ketones, alcohols and other bio-oil compounds. Phenols showed the highest decrease, with a maximum reduction of 8.63 %. Aldehydes, acids and hydrocarbons showed an increasing trend, with aldehydes exhibiting the highest increase of 11.06 %. Furans and esters remained relatively unchanged. This study will provide guidance for the changes in bio-oil compound composition during biomass pyrolysis and the high-value utilization of bio-oil. [Display omitted]
ISSN:1876-1070
1876-1089
DOI:10.1016/j.jtice.2024.105475