Isolation and Characterization of Nanocellulose from Polypodiophyta Fern Using Chemo-Mechanical Method.

IF 3.4 3区 医学 Q1 ENGINEERING, MULTIDISCIPLINARY
Katja Vasić, Monika Dokl, Željko Knez, Maja Leitgeb
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Abstract

Nanocellulose is considered a promising and sustainable biomaterial, with excellent properties of biorenewability with improved mechanical properties. As a unique natural biopolymer, it has been applied to many different industries, where efficient and environmentally friendly productions are in demand. For the first time, ferns from the class Polypodiopsida were used for the isolation of cellulose fibers, which was performed using a chemo-mechanical method. As chemical treatment plays a crucial role in the isolation of nanocellulose, it affects the efficiency of the extraction process, as well as the properties of the resulting nanocellulose. Therefore, mechanical fibrillation was performed via grinding, while the chemical process consisted of three different treatments: alkali treatment, bleaching, and acid hydrolysis. In three different experiments, each treatment was separately prolonged to investigate the differing properties of isolated nanocellulose. Structural analysis and morphological analysis were investigated by SEM, EDS, FT-IR, and DLS. The thermal stability of cellulose fibers was investigated by TGA/DSC. The morphology of obtained nanocellulose was confirmed via SEM analysis for all samples, with particles ranging from 20 nm up to 600 nm, while the most consistent sizes were observed for NC3, ranging from 20 to 60 nm. FT-IR spectra showed prominent absorption peaks corresponding to cellulose, as well as the absence of absorption peaks, corresponding to lignin and hemicellulose. The EDS confirmed the elemental purity of nanocellulose, while TGA/DSC indicated higher thermal stability of nanocellulose, compared to untreated fern, which started to degrade earlier than nanocellulose. Such characteristics with unique properties make nanocellulose a versatile biomaterial for the industrial production of cellulosic materials.

利用化学机械方法从蕨类植物中分离和表征纳米纤维素
纳米纤维素被认为是一种前景广阔的可持续生物材料,具有优异的生物可再生性和更好的机械性能。作为一种独特的天然生物聚合物,它已被应用于许多不同的行业,这些行业都需要高效、环保的产品。首次使用化学机械方法分离纤维素纤维时,使用的是多足目蕨类植物。由于化学处理在纳米纤维素的分离过程中起着至关重要的作用,它会影响萃取过程的效率以及所得纳米纤维素的特性。因此,机械纤维化是通过研磨进行的,而化学处理则包括三种不同的处理方法:碱处理、漂白和酸水解。在三个不同的实验中,分别延长了每种处理方法的时间,以研究分离出的纳米纤维素的不同特性。通过扫描电镜、EDS、傅立叶变换红外光谱和 DLS 对结构分析和形态分析进行了研究。通过 TGA/DSC 研究了纤维素纤维的热稳定性。所有样品的扫描电镜分析都证实了所获得的纳米纤维素的形态,其颗粒大小从 20 纳米到 600 纳米不等,而 NC3 的颗粒大小最为一致,从 20 纳米到 60 纳米不等。傅立叶变换红外光谱显示出与纤维素相对应的突出吸收峰,以及与木质素和半纤维素相对应的无吸收峰。EDS 证实了纳米纤维素的元素纯度,而 TGA/DSC 则表明,与未经处理的蕨类植物相比,纳米纤维素具有更高的热稳定性,后者比纳米纤维素更早开始降解。这些独特的特性使纳米纤维素成为一种多功能生物材料,可用于纤维素材料的工业生产。
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来源期刊
Biomimetics
Biomimetics Biochemistry, Genetics and Molecular Biology-Biotechnology
CiteScore
3.50
自引率
11.10%
发文量
189
审稿时长
11 weeks
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