Coupled effect of pyrolysis temperature and HNO3 pretreatment on sugarcane bagasse fast pyrolysis for levoglucosan production

IF 5.8 2区生物学 Q1 AGRICULTURAL ENGINEERING

Biomass & Bioenergy Pub Date : 2025-09-11 DOI:10.1016/j.biombioe.2025.108372

Geraldo Ferreira David , Rodolfo Roberto Moreno-Parra , Victor Haber Perez , Thays da Costa Silveira , Euripedes Garcia Silveira Junior , Oselys Rodriguez Justo , Manuel Garcia-Perez

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Abstract

This work aimed to evaluate the potential of HNO₃ (0.1 wt%) in the pretreatment of sugarcane bagasse as a strategy to intensify levoglucosan production, before subjecting it to fast pyrolysis under different temperature conditions. The experiments were conducted in a pyroprobe reactor coupled to a GC/MS at temperatures ranging from 350 to 600 °C, with 50 °C intervals. Thus, in addition to the impact of nitric acid on levoglucosan yield, the formation profile of other pyrolytic derivatives during the thermochemical conversion of biomass is reported. The best results regarding levoglucosan yield were obtained when pyrolysis was performed at 450 °C, resulting in approximately twice the amount of levoglucosan obtained from sugarcane bagasse after treating the biomass with acid compared to the control (untreated biomass), while the profiles of the other pyrolytic derivatives identified showed different and lower behaviors after acid washing of the biomass. The observed effect may be due not only to the removal of alkali and alkaline earth metals, whose catalytic activity influences the pyrolytic pathways, but also to the probable partial removal of lignin and/or hemicellulose fractions by the acid washing. On the other hand, despite the observed increase in levoglucosan formation, the results obtained with HNO₃ at 0.1 % by biomass weight do not seem to be a good alternative for the intensification of the target compound, when compared with other acids used in washing/passivation procedures of sugarcane bagasse under similar experimental conditions.

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热解温度与HNO3预处理对蔗渣快速热解制备左旋葡聚糖的耦合影响

本研究旨在评估HNO3 （0.1 wt%）在蔗渣预处理中作为强化左旋葡聚糖生产策略的潜力，然后在不同温度条件下对其进行快速热解。实验在高温探针反应器中耦合GC/MS进行，温度范围为350 ~ 600℃，间隔为50℃。因此，除了硝酸对左旋葡聚糖产率的影响外，还报道了生物质热化学转化过程中其他热解衍生物的形成情况。在450°C的温度下进行热解时，左旋葡聚糖的产率最高，用酸处理蔗渣得到的左旋葡聚糖的量约为对照（未处理的生物质）的两倍，而其他热解衍生物在生物质酸洗后表现出不同且较低的行为。观察到的效果可能不仅是由于碱金属和碱土金属的去除，其催化活性影响热解途径，而且还可能是由于酸洗部分去除木质素和/或半纤维素组分。另一方面，尽管观察到左旋葡聚糖的形成增加，但与在类似实验条件下用于蔗渣洗涤/钝化过程的其他酸相比，在0.1%的HNO3下获得的结果似乎不是强化目标化合物的好选择。

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来源期刊

Biomass & Bioenergy 工程技术-能源与燃料

CiteScore

11.50

自引率

3.30%

发文量

258

审稿时长

60 days

期刊介绍： Biomass & Bioenergy is an international journal publishing original research papers and short communications, review articles and case studies on biological resources, chemical and biological processes, and biomass products for new renewable sources of energy and materials. The scope of the journal extends to the environmental, management and economic aspects of biomass and bioenergy. Key areas covered by the journal: • Biomass: sources, energy crop production processes, genetic improvements, composition. Please note that research on these biomass subjects must be linked directly to bioenergy generation. • Biological Residues: residues/rests from agricultural production, forestry and plantations (palm, sugar etc), processing industries, and municipal sources (MSW). Papers on the use of biomass residues through innovative processes/technological novelty and/or consideration of feedstock/system sustainability (or unsustainability) are welcomed. However waste treatment processes and pollution control or mitigation which are only tangentially related to bioenergy are not in the scope of the journal, as they are more suited to publications in the environmental arena. Papers that describe conventional waste streams (ie well described in existing literature) that do not empirically address ''new'' added value from the process are not suitable for submission to the journal. • Bioenergy Processes: fermentations, thermochemical conversions, liquid and gaseous fuels, and petrochemical substitutes • Bioenergy Utilization: direct combustion, gasification, electricity production, chemical processes, and by-product remediation • Biomass and the Environment: carbon cycle, the net energy efficiency of bioenergy systems, assessment of sustainability, and biodiversity issues.