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硬木木质素共混对纤维素基碳纤维电学和力学性能的影响。

Influence of Hardwood Lignin Blending on the Electrical and Mechanical Properties of Cellulose Based Carbon Fibers.

作者信息

Rajendra Babu Kalai Arasi Azega, Bengtsson Jenny, Haque Mazharul, Theliander Hans, Enoksson Peter, Lundgren Per

机构信息

Department of Microtechnology and Nanoscience, Chalmers University of Technology, 41296 Göteborg, Sweden.

Wallenberg Wood Science Center, 100 44 Stockholm, Sweden.

出版信息

ACS Sustain Chem Eng. 2024 Jul 15;12(30):11206-11217. doi: 10.1021/acssuschemeng.4c02052. eCollection 2024 Jul 29.

DOI:10.1021/acssuschemeng.4c02052
PMID:39091924
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11289755/
Abstract

Carbon fibers (CFs) are fabricated by blending hardwood kraft lignin (HKL) and cellulose. Various compositions of HKL and cellulose in blended solutions are air-gap spun in 1-ethyl-3-methylimidazolium acetate (EMIM OAc), resulting in the production of virtually bead-free quality fibers. The synthesized HKL-cellulose fibers are thermostabilized and carbonized to achieve CFs, and consequently their electrical and mechanical properties are evaluated. Remarkably, fibers with the highest lignin content (65%) exhibited an electrical conductivity of approximately 42 S/cm, surpassing that of cellulose (approximately 15 S/cm). Moreover, the same fibers demonstrated significantly improved tensile strength (∼312 MPa), showcasing a 5-fold increase compared to pure cellulose while maintaining lower stiffness. Comprehensive analyses, including Auger electron spectroscopy and wide-angle X-ray scattering, show a heterogeneous skin-core morphology in the fibers revealing a higher degree of preferred orientation of carbon components in the skin compared to the core. The incorporation of lignin in CFs leads to increased graphitization, enhanced tensile strength, and a unique skin-core structure, where the skin's graphitized cellulose and lignin contribute stiffness, while the predominantly lignin-rich core enhances carbon content, electrical conductivity, and strength.

摘要

碳纤维(CFs)是通过将硬木硫酸盐木质素(HKL)与纤维素混合制成的。混合溶液中不同组成的HKL和纤维素在1-乙基-3-甲基咪唑醋酸盐(EMIM OAc)中进行气隙纺丝,从而生产出几乎无珠的优质纤维。合成的HKL-纤维素纤维经过热稳定化和碳化处理以获得CFs,进而对其电学和力学性能进行评估。值得注意的是,木质素含量最高(65%)的纤维表现出约42 S/cm的电导率,超过了纤维素(约15 S/cm)。此外,相同的纤维显示出显著提高的拉伸强度(约312 MPa),与纯纤维素相比提高了5倍,同时保持较低的刚度。包括俄歇电子能谱和广角X射线散射在内的综合分析表明,纤维具有异质的皮芯形态,与芯部相比,皮层中碳成分的择优取向程度更高。在CFs中加入木质素会导致石墨化增加、拉伸强度提高以及独特的皮芯结构,其中皮层中石墨化的纤维素和木质素提供刚度,而主要富含木质素的芯部则提高碳含量、电导率和强度。

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