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TEMPO氧化体系中催化剂和氧化剂浓度对纤维素纳米纤维产量的影响。

Effect of catalyst and oxidant concentrations in a TEMPO oxidation system on the production of cellulose nanofibers.

作者信息

Park Jisoo, Lee Danbee, Hwang Kyojung, Lee Jimin, Lee Tai-Ju, Kim Youngsu, Kim Jung Hyeun, Lee Jieun, Youe Won-Jae, Chun Sang-Jin, Gwon Jaegyoung

机构信息

National Institute of Forest Science 57 Hoegi-ro, Dongdaemun-gu Seoul 02455 South Korea

Daeshin University 33 Gyeongcheong-ro 222-gil Gyeongsan Gyeongsangbukdo 38649 South Korea.

出版信息

RSC Adv. 2024 Oct 17;14(45):32852-32862. doi: 10.1039/d4ra04948a.

DOI:10.1039/d4ra04948a
PMID:39429929
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11484588/
Abstract

In traditional TEMPO oxidation systems, the high cost of TEMPO catalysts has been a significant barrier to the industrialization of oxidized CNF. From an economic perspective, presenting the characteristics of various CNFs produced with the oxidation systems with reduced catalyst usage could facilitate the industrial application of CNF across a wide range of fields. In this study, it was demonstrated that reducing the amount of TEMPO catalyst used (from 0.1 to 0.05 mmol g) in a conventional oxidation system increased the carboxylate content by approximately 6.3%. Furthermore, the activation of hydroxyl amine TEMPO, which is generated after the oxidation reaction of cellulose, was enhanced by adjusting the dosage of the inexpensive oxidant NaClO, leading to a 20% improvement in carboxylate content. This suggests that controlling the amount of NaClO as an oxidant can be a key parameter in adjusting the dosage of TEMPO to achieve the targeted degree of surface substitution. Results from the dispersion stability, UV-transmittance, and morphological properties of TEMPO-oxidized CNF using microfluidizing treatment showed that high carboxylate content plays a crucial role in producing high-purity CNF suspensions, which are small, uniform, and free from microfibers. Additionally, by varying the number of mechanical treatments applied to the oxidized cellulose, various types of CNF suspensions with different mean widths were obtained. We expect that these findings offer meaningful insights to end-users seeking a breakthrough in the performance limitations of final applications using cellulose nanomaterials.

摘要

在传统的TEMPO氧化体系中,TEMPO催化剂的高成本一直是氧化纤维素纳米纤维(CNF)工业化的重大障碍。从经济角度来看,介绍使用减少催化剂用量的氧化体系生产的各种CNF的特性,有助于CNF在广泛领域的工业应用。在本研究中,结果表明,在传统氧化体系中减少TEMPO催化剂的用量(从0.1 mmol/g降至0.05 mmol/g),羧酸盐含量提高了约6.3%。此外,通过调整廉价氧化剂次氯酸钠(NaClO)的用量,可增强纤维素氧化反应后生成的羟胺TEMPO的活性,使羧酸盐含量提高20%。这表明,控制作为氧化剂的NaClO的用量可能是调整TEMPO用量以达到目标表面取代度的关键参数。对经微流化处理的TEMPO氧化CNF的分散稳定性、紫外透过率和形态特性的研究结果表明,高羧酸盐含量在制备高纯度CNF悬浮液方面起着关键作用,该悬浮液粒径小、均匀且无微纤维。此外,通过改变对氧化纤维素进行机械处理的次数,可获得具有不同平均宽度的各种类型的CNF悬浮液。我们期望这些发现能为寻求突破纤维素纳米材料最终应用性能限制的终端用户提供有意义的见解。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/fe75/11484588/536124ba0083/d4ra04948a-f7.jpg
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