臭氧分解对油棕果中果皮木质素化的影响

IF 1.3 Q4 ENGINEERING, ENVIRONMENTAL

Journal of Ecological Engineering Pub Date : 2024-07-01 DOI:10.12911/22998993/188879

Asyeni Miftahul Jannah Asyeni, Muhammad Faizal, Novia Novia, H. Widjajanti

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引用次数: 0

摘要

油棕果中果皮（OPFM）是一种含有纤维素的固体副产品，有可能成为生物燃料的原料。这种固体副产品中的纤维素可以通过脱木质化提取出来。因此，本研究旨在调查臭氧在 OPFM 脱木素过程中的应用，以分解材料中的木质素键。在分析过程中，臭氧分解脱木质受粒度、氧气流速和反应时间的影响。臭氧流速采用碘量法进行分析。使用 α - 纤维素法、γ - 纤维素法和 Kappa 法分析了原料和处理样品中的纤维素、半纤维素和木质素含量。结果表明，在粒度为 100 目、流速为 2 升/分钟-1、时间为 15 分钟的条件下，臭氧可去除 42.03% 的木质素、15.89% 的半纤维素，并浓缩 62.85% 的纤维素。扫描电镜和傅立叶变换红外光谱分析结果表明，臭氧溶解脱木素后，OPFM 中的半纤维素和木质素被去除。此外，XRD 分析表明了高纤维素产量的结晶度。

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The Effects of Ozonolysis on Oil Palm Fruit Mesocarp Delignification

Oil palm fruit mesocarp (OPFM) is a solid by-product containing cellulose, potentially serving as a raw material for biofuel. The cellulose content of this solid by-product can be extracted through delignification. Therefore, this study aimed to investigate the application of ozone for OPFM delignification to break down lignin bonds in the material. During the analysis, ozonolysis delignification was influenced by particle size, oxygen flow rate, and reaction time. Ozone flowrate analyzed using the Iodometric method. Cellulose, hemicellulose, and lignin content of raw material and treated samples were analyzed using the α – cellulose, γ – cellulose, and the Kappa method. The results showed that by using a particle size of 100 mesh, and a flow rate of 2 Lmin -1 for 15 min, ozone de - graded 42.03% lignin, 15.89% hemicellulose, and concentrated 62.85% cellulose. SEM and FTIR results showed the removal of hemicellulose and lignin from OPFM with ozonolysis delignification. Furthermore, XRD analysis showed the crystallinity degree of the high cellulose yield.

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来源期刊

Journal of Ecological Engineering ENGINEERING, ENVIRONMENTAL-

CiteScore

2.60

自引率

15.40%

发文量

379

审稿时长

8 weeks

期刊介绍： - Industrial and municipal waste management - Pro-ecological technologies and products - Energy-saving technologies - Environmental landscaping - Environmental monitoring - Climate change in the environment - Sustainable development - Processing and usage of mineral resources - Recovery of valuable materials and fuels - Surface water and groundwater management - Water and wastewater treatment - Smog and air pollution prevention - Protection and reclamation of soils - Reclamation and revitalization of degraded areas - Heavy metals in the environment - Renewable energy technologies - Environmental protection of rural areas - Restoration and protection of urban environment - Prevention of noise in the environment - Environmental life-cycle assessment (LCA) - Simulations and computer modeling for the environment