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基于分级和充分的结构解释定制工业木质素利用策略,以生产吸附剂和絮凝剂。

Customized Utilization Strategies of Industrial Lignin to Produce Adsorbents and Flocculants Based on Fractionation and Adequate Structural Interpretation.

机构信息

Hubei Provincial Key Laboratory of Green Materials for Light Industry, School of Materials and Chemical Engineering, Hubei University of Technology, Wuhan 430068, China.

School of Engineering, Jining University, Qufu 273155, China.

出版信息

Int J Mol Sci. 2022 Jun 14;23(12):6617. doi: 10.3390/ijms23126617.

DOI:10.3390/ijms23126617
PMID:35743071
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9223612/
Abstract

Lignin, a by-product of pulping and biorefinery, has great potential to replace petrochemical resources for wastewater purification. However, the defects of lignin, such as severe heterogeneity, inferior reactivity and poor solubility, characterize the production process of lignin-based products by high energy consumption and serious pollution. In this study, several lignin fractions with relatively homogeneous structure were first obtained by organic solvent fractionation, and their structures were fully deciphered by various characterization techniques. Subsequently, each lignin component was custom-valued for wastewater purification based on their structural characteristics. Benefiting from the high reactivity and reaction accessibility, the lignin fraction (lignin-1) refined by dissolving in ethanol and n-butanol could been used as a raw material to produce cationic lignin-based flocculant (LBF) in a copolymerization system using green, cheap and recyclable ethanol as solvent. The lignin fraction (lignin-2) extracted by methanol and dioxane showed low reactivity and high carbon content, which was used to produce lignin-based activated carbon (LAC) with phosphoric acid as activator. Moreover, the influences of synthetic factors on the purification capacity were discussed, and the LBF and LAC produced under the optimal conditions showed distinguished purification effect on kaolin suspension and heavy metal wastewater, respectively. Furthermore, the corresponding purification mechanism and external factors were also elaborated. It is believed that this cleaner production strategy is helpful for the valorization of lignin in wastewater resources.

摘要

木质素是制浆和生物炼制的副产品,具有替代石化资源用于废水净化的巨大潜力。然而,木质素的缺陷,如严重的不均匀性、较差的反应性和较差的溶解性,使得基于木质素的产品的生产过程具有高能耗和严重污染的特点。在本研究中,首先通过有机溶剂分级法获得了几个具有相对均匀结构的木质素级分,并通过各种表征技术对其结构进行了充分解析。随后,根据其结构特征,对每种木质素组分进行了定制化的废水净化。由于高反应性和反应可及性,通过在乙醇和正丁醇中溶解精制的木质素级分(木质素-1)可作为原料,在以绿色、廉价和可回收的乙醇为溶剂的共聚体系中生产阳离子木质素基絮凝剂(LBF)。用甲醇和二恶烷提取的木质素级分(木质素-2)反应性低、碳含量高,可用作磷酸活化剂生产木质素基活性炭(LAC)。此外,还讨论了合成因素对净化能力的影响,在最佳条件下制备的 LBF 和 LAC 对高岭土悬浮液和重金属废水分别表现出显著的净化效果。此外,还阐述了相应的净化机制和外部因素。相信这种清洁生产策略有助于实现废水资源中木质素的增值利用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3f5a/9223612/f9fe89ed2978/ijms-23-06617-sch002.jpg
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