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二甲基亚砜/氯化锂溶解再生制备植物纤维纳米颗粒 被引量:1

Preparation of Plant Lignocelluloses′ Nano Particles by Dissolution and Regeneration DMSO/LiCl System
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摘要 以阔叶树杨木为原料,二甲基亚砜/氯化锂(DMSO/LiCl)为溶剂,水为再生液,在温和的条件下先溶解杨木木粉,然后在水中再生为悬浮液,经过一系列工序制备成植物纤维纳米颗粒。考察了溶解温度、木粉用量、LiCl在DMSO中的质量分数等因素对杨木粉溶解率的影响,同时考察了再生时转速、羧甲基纤维素钠(CMC-Na)用量对悬浮液粒径的影响。实验表明当溶解温度为70℃,木粉与溶剂的质量比为3∶100,LiCl在DMSO中的质量分数为8%时杨木粉溶解率最大55.6%;再生转速为2 000 r/min,CMC-Na对木粉的质量比为1∶100时再生悬浮液的粒径最小为85 nm。用傅里叶变换红外光谱(FT-IR)、马尔文粒径仪、扫描电镜(SEM)、透射电镜(TEM)和热重(TG)等对原料和产物的相关性质进行了表征。实验结果表明,该方法制备的植物纤维纳米颗粒,有效地提高了植物纤维比表面积,将可以广泛应用于新型材料、精细化学品等中作为新型纳米材料。 Micro-nano particles of plant lignocelluloses were prepared and characterized in present study. The poplar wood were milled to be powders and then dissolved in DMSO/LiC1. The dissolved powders were regenerated to be stable suspensions in the water and dried to be micro-nano particles with spray drying under mild conditions. The factors affecting the preparation processes were investigated and optimized. The results showed that the dissolution ratio reached to maximum 55.6 % when the temperature was 70 ~C, the solid and liquid mass ratio was 3 : 100, the mass ratio of LiC1 in DMSO was 8 %. The suspension particle size reached the minimum 85 nm when the rotational speed of the high speed dispersion machine was 2 000 r/min, the mass ratio of CMC-Na and wood was 1%. The raw materials and products were characterized by FT-IR, Malvern Zetasizer instrument, SEM, TEM and TG, respectively. It was revealed that micro-nano particles of the plant fiber made by this method possessed a higher specific surface area and they could be used as new fine chemical nano-materials.
作者 张磊 叶代勇
机构地区 华南理工大学化学与化工学院
出处 《林产化学与工业》 EI CAS CSCD 北大核心 2013年第3期31-37,共7页 Chemistry and Industry of Forest Products
基金 广东省自然科学基金(07300767)
关键词 植物纤维 纳米颗粒 DMSO LICL 溶解 再生 lignocelluloses nano particles dimethylsufoxide/lithium chloride (DMSO/LiC1) dissolution regeneration
分类号 TQ352.79 [化学工程]
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参考文献18

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林产化学与工业
2013年 第3期

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