黏弹性表面活性剂(Ⅴ)OA

Viscoelastic surfactants(Ⅴ)Similarity and difference between wormlike micelles and polymers

中文摘要英文摘要

蠕虫状胶束可通过自组装形成类聚合物长链缠结结构,宏观呈现优异黏弹性流变特征,被称为"活聚合物",在流变改性领域与传统聚合物存在诸多表观共性.本文主要对比了C22-尾基EDAB两性表面活性剂蠕虫状胶束与超高分子量(12×106 g/mol)非离子聚丙烯酰胺(PAM)以及十六烷基氯化吡啶/水杨酸钠(CPyCl/NaSal)蠕虫状胶束与聚苯乙烯两组体系,从宏观流变、微观结构、动力学机制多维度系统对比二者的相似特征与本质差异.结果表明,二者在长链拓扑结构、缠结增稠机制、温变流变规律上高度重合,但组装方式、结构稳定性、弛豫机制存在根本性区别.蠕虫状胶束为非共价动态平衡体系,具备双重弛豫机制与灵敏环境响应性,增稠效率显著优于聚合物;传统聚合物依托共价键结构,性能稳定、无动态重构特性.本文明确二者类比的适用边界与性能差异,为两类软物质材料的精准应用与理论完善提供支撑.

Wormlike micelles(WLMs)are self-assembled,one-dimensional aggregates that form transient entangled networks in aqueous solutions,exhibiting macroscopic rheology akin to that of traditional water-soluble polymers.This behavioral resemblance has fostered the"living polymer"analogy,yet the underlying assembly mechanisms differ fundamentally—a source of persistent ambiguity in both theory and application.To clarify these similarities and distinctions,a comparative study was reviewed on C22-tailed ultra-long zwitterionic EDAB wormlike micelles and ultra-high molecular weight(12×106 g/mol)polyacrylamide(PAM)using macroscopic rheology,small-angle neutron scattering,cryo-transmission electron microscopy,and reptation theory.Both systems behave as semi-flexible chains that form entangling networks above a critical overlap concentration,display shear thinning at high rates,and follow Arrhenius temperature dependence(25-85℃),with optimal zero-shear viscosity reaching 40 000 mPa·s.Despite these parallels,their internal assembly modes diverge fundamentally.Traditional polymers rely on permanent covalent bonds—fixed chain length,molecular weight,and single reptation relaxation.In contrast,WLMs arise from reversible non-covalent hydrophobic and electrostatic interactions,yielding a thermodynamically balanced dynamic system with continuous breakage-reorganization and molecular exchange.Consequently,EDAB micelles exhibit 2.5-fold higher thickening efficiency and a lower critical overlap concentration(0.04 wt%)than PAM.They also show markedly higher temperature sensitivity(flow activation energy:145 kJ/mol for EDAB vs.24 kJ/mol for PAM).While polymers display a multi-mode relaxation spectrum,WLMs obey Maxwell single-relaxation behavior at elevated temperatures and feature a dual relaxation mechanism coupling breakage with reptation.Morphologically,WLMs possess a larger core radius(~2.9 nm)and persistence length(≥20 nm),with temperature-induced reversible transitions(shortening,branching,cyclization);polymer structures remain stable.Thus,the similarity between wormlike micelles and polymer solutions is only superficial under low concentrations and mild conditions;their essential dynamic and thermodynamic differences govern performance under complex environments.This analysis delineates the valid scope of the"living polymer"analogy and offers a theoretical basis for targeted design and application of both rheology modifiers.

冯玉军

四川大学 高分子研究所 先进高分子材料工程全国重点实验室,四川 成都 610065

化学化工

蠕虫状胶束聚合物流变性微观结构流变改性剂

wormlike micellespolymerrheologymicrostructurerheology modifier

《日用化学工业(中英文)》 2026 (5)

557-563,7

国家自然科学基金项目(No.U22A2039521173207)

10.3969/j.issn.2097-2806.2026.05.001

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