Comparative study of oxidized cellulose nanofibrils properties from diverse sources via TEMPO-mediated oxidation

Q1 Environmental Science
Agus Wedi Pratama , Bambang Piluharto , Melbi Mahardika , Nurul Widiastuti , Afrinal Firmanda , Mohd Nor Faiz Norrrahim
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Abstract

Cellulose nanofibrils (CNF) are promising renewable materials due to their high surface area, abundance, and ease of modification. This study explores the impact of source material on CNF properties for diverse applications like drug delivery and composites. CNF were prepared from corn cob (CC), bagasse (BG), waste wood (WW), and bacterial cellulose (BC) using TEMPO-mediated oxidation. Microcrystalline cellulose (MCC) was also oxidized (MCC-ox) for comparison. The transparency, chemical structure, crystallinity index, and surface charge of the resulting CNF were investigated. As a result, all CNF yields ranged from 25 % to 34 %. FT-IR analysis confirmed successful TEMPO oxidation by detecting carboxyl groups on all CNF surfaces. BC-derived CNF displayed the second-highest transparency after MCC. Surface charge analysis revealed the highest carboxyl content in MCC-ox (8828.39 mmol/kg), followed by CNF-BC (8438.84 mmol/kg), CNF-CC (7687.24 mmol/kg), CNF-WW (6720.43 mmol/kg), and CNF-BG (5505.61 mmol/kg). XRD analysis indicated the highest crystallinity index in MCC-ox (83.40 %) due to its high purity, followed by CNF-BC (82.52 %) likely due to its nanostructure and high purity, and CNF-CC (78.14 %) potentially due to the rigid and dense structure of corn cobs. These findings provide valuable insights into selecting CNF with the desired characteristics for various fields such as material science, nanotechnology, and biomedicine.

Abstract Image

通过 TEMPO 介导的氧化作用比较研究不同来源的氧化纤维素纳米纤维的特性
纤维素纳米纤维(CNF)具有表面积大、数量多、易于改性等特点,是一种前景广阔的可再生材料。本研究探讨了源材料对 CNF 性能的影响,以便将其用于药物输送和复合材料等多种应用。利用 TEMPO 媒介氧化法,从玉米芯 (CC)、甘蔗渣 (BG)、废木材 (WW) 和细菌纤维素 (BC) 中制备了 CNF。微晶纤维素(MCC)也被氧化(MCC-ox),以作比较。研究了所得 CNF 的透明度、化学结构、结晶度指数和表面电荷。结果,所有 CNF 的产量在 25 % 到 34 % 之间。傅立叶变换红外分析通过检测所有 CNF 表面的羧基,证实了 TEMPO 氧化反应的成功。BC 衍生的 CNF 透明度仅次于 MCC。表面电荷分析表明,MCC-ox 的羧基含量最高(8828.39 mmol/kg),其次是 CNF-BC(8438.84 mmol/kg)、CNF-CC(7687.24 mmol/kg)、CNF-WW(6720.43 mmol/kg)和 CNF-BG(5505.61 mmol/kg)。XRD 分析表明,MCC-ox 的结晶度指数最高(83.40%),这是因为其纯度高,其次是 CNF-BC(82.52%),这可能是由于其纳米结构和纯度高,而 CNF-CC(78.14%)可能是由于玉米芯的刚性和致密结构。这些发现为材料科学、纳米技术和生物医学等不同领域选择具有所需特性的 CNF 提供了宝贵的见解。
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来源期刊
Case Studies in Chemical and Environmental Engineering
Case Studies in Chemical and Environmental Engineering Engineering-Engineering (miscellaneous)
CiteScore
9.20
自引率
0.00%
发文量
103
审稿时长
40 days
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