Laurel L. Kegel, Yu-Cheng Wang, Lajos Z. Szabó, Robin Polt, Jeanne E. Pemberton
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引用次数: 0
Abstract
The lyotropic properties of alkyl thioglycosides with varying sugar headgroup (lactose, cellobiose, maltose, galactose, or glucose) and alkyl chain length (octyl, decyl, or dodecyl chains) are investigated by surface tensiometry, visual observation, and fluorescence spectroscopy. The results substantiate that the glycosidic S-linkage confers considerably different solution aggregation behavior on these surfactants relative to their O-linked counterparts, where the properties of the latter are known. The materials properties of the aggregated structures from the alkyl thioglycosides vary considerably. Micelles are formed by octyl thiocellobioside and all alkyl thiomaltosides. Turbid aggregate solutions are formed by the alkyl thioglucosides and octyl thiogalactoside, whereas the longer chain alkyl thiogalactosides are minimally soluble. Fluorescence spectroscopy of these systems confirms their aggregation in lamellar-like structures. The alkyl thiocellobiosides and alkyl thiolactosides form hydrogels from these low-molecular weight materials at concentrations almost an order of magnitude lower than gels using other low-molecular weight materials. Here, hydrogels form at concentrations <0.3 wt% with some forming hydrogels at concentrations as low as 0.03 wt% from alkyl thiocellobiosides and thiolactosides, with hydrogel properties differing significantly with this slight change in the sugar headgroup. Alkyl thiocellobiosides form a nanofiber network and alkyl thiolactosides form globular hydrogels. Overall, these results clearly document materials properties that can readily be controlled and designed depending on molecular structure.
本研究通过表面张力测定法、肉眼观察法和荧光光谱法研究了具有不同糖头基(乳糖、纤维生物糖、麦芽糖、半乳糖或葡萄糖)和烷基链长度(辛基链、癸基链或十二烷基链)的烷基硫代糖苷的溶胀特性。研究结果证明,糖苷 S 键使这些表面活性剂的溶液聚集行为与 O 键表面活性剂大不相同,而后者的特性是已知的。烷基巯基糖苷聚集结构的材料特性差异很大。辛基硫代生物糖苷和所有烷基硫代麦芽糖苷都能形成胶束。烷基硫代葡萄糖苷和辛基硫代半乳糖苷会形成浑浊的聚合溶液,而长链烷基硫代半乳糖苷的溶解度很小。这些体系的荧光光谱证实了它们聚集成片状结构。烷基硫代生物糖苷和烷基硫代半乳糖苷在这些低分子量材料中形成水凝胶的浓度几乎比使用其他低分子量材料形成的凝胶低一个数量级。其中,烷基硫代生物糖苷和硫代半乳糖苷在浓度为 0.3 wt%时就能形成水凝胶,而有些水凝胶在浓度低至 0.03 wt%时就能形成,糖头基团的细微变化也会导致水凝胶性质的显著不同。烷基硫代生物糖形成纳米纤维网,烷基硫代乳糖形成球状水凝胶。总之,这些结果清楚地证明了材料的特性可以根据分子结构进行控制和设计。
期刊介绍:
Journal of Surfactants and Detergents, a journal of the American Oil Chemists’ Society (AOCS) publishes scientific contributions in the surfactants and detergents area. This includes the basic and applied science of petrochemical and oleochemical surfactants, the development and performance of surfactants in all applications, as well as the development and manufacture of detergent ingredients and their formulation into finished products.