Formation of soluble organics and sugar degradation byproduct during hot compressed water pre-treatment of empty fruit bunch for biogas production

IF 5.8 2区生物学 Q1 AGRICULTURAL ENGINEERING

Biomass & Bioenergy Pub Date : 2025-05-06 DOI:10.1016/j.biombioe.2025.107960

Adila Fazliyana Aili Hamzah , Muhammad Hazwan Hamzah , Khairudin Nurulhuda , Hasfalina Che Man , Muhammad Heikal Ismail , Pau Loke Show

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Abstract

To assess the potential for improvements in soluble organics formation, biogas production, and inhibitory effects resulting from the concurrent generation of furan byproducts, palm oil empty fruit bunches (EFB) were subjected to hot compressed water (HCW) treatment at high temperatures and extended reaction times. The application of HCW pre-treatment at temperatures ranging from 180 °C to 220 °C for 5–60 min was found to greatly enhance the formation of soluble organic compounds and furan derivatives derived from EFB. However, only the pre-treatment carried out at 180 °C for a duration of 15 min led to a significantly greater biogas yield of 710.45 mL CH₄/gVS. Biogas yields decreased under severe pre-treatment conditions (200–220 °C), likely due to the inhibitory effects of furfural and 5-hydroxymethylfurfural (5-HMF). Then, a co-digestion system was simulated to assess the inhibitory impact of furfural and 5-HMF on biogas production. Kinetic inhibition models were used to determine the threshold at which these substances became inhibitory. Furfural and 5-HMF's inhibitory threshold was found to be 2000 mg/L. The Haldane model proved to be the most suitable for simulating the inhibitory effect of furfural, whereas the Aiba model was well-suited for simulating the impact of 5-HMF in the anaerobic co-digestion process. The current study novelty lies in identifying the limitation of HCW pre-treatment for biogas production. By elucidating the inhibitory effect of furan derivatives, it provides clear guidance for mitigating the inhibition caused by furfural and 5-HMF.

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空果束热压缩水预处理制气过程中可溶性有机物和糖降解副产物的形成

为了评估在可溶性有机物形成、沼气生产和呋喃副产品同时产生的抑制效应方面的改善潜力，棕榈油空果束（EFB）在高温和延长反应时间下进行了热压缩水（HCW）处理。在180 ~ 220℃的温度下进行5 ~ 60 min的HCW预处理，可以极大地促进EFB的可溶性有机化合物和呋喃衍生物的形成。然而，只有在180°C下进行15分钟的预处理才能显著提高沼气产量，达到710.45 mL CH4/gVS。在严酷的预处理条件下（200-220°C），沼气产量下降，可能是由于糠醛和5-羟甲基糠醛（5-HMF）的抑制作用。然后，模拟共消化系统，评估糠醛和5-羟甲基糠醛对沼气产生的抑制作用。动力学抑制模型用于确定这些物质成为抑制的阈值。糠醛和5-HMF的抑制阈值为2000 mg/L。Haldane模型最适合模拟糠醛的抑制作用，Aiba模型最适合模拟5-HMF在厌氧共消化过程中的影响。当前研究的新颖性在于确定HCW预处理用于沼气生产的局限性。通过阐明呋喃衍生物的抑制作用，为减轻呋喃和5-羟甲基糠醛引起的抑制作用提供明确的指导。

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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.