Bhargava Prachur, Tu Yingfeng, Zheng Joseph X, Xiong Huiming, Quirk Roderic P, Cheng Stephen Z D
The Maurice Morton Institute and Department of Polymer Science, The University of Akron, Akron, Ohio 44325-3909, USA.
J Am Chem Soc. 2007 Feb 7;129(5):1113-21. doi: 10.1021/ja0653019.
Temperature-induced reversible morphological changes of polystyrene-block-poly(ethylene oxide) micelles with degrees of polymerization of 962 for the PS and 227 for the PEO blocks (PS962-b-PEO227) in N,N-dimethylformamide (DMF)/water, in which water is a selective solvent for the PEO block, were observed. For a system with 0.2 wt % copolymer concentration and 4.5 wt % water concentration in DMF/water, the micelle morphology observed in transmission electron microscopy changed from vesicles at room temperature to worm-like cylinders and then to spheres with increasing temperature. Mixed morphologies were also formed in the intermediate temperature regions. Cooling the system back to room temperature regenerated the vesicle morphology, indicating that the morphological changes were reversible. No hysteresis was observed in the morphological changes during heating and cooling. Dynamic light scattering revealed that the hydrodynamic radius of the micelles decreased with increasing temperature. Combined static and dynamic light scattering results supported the change in morphology with temperature. The critical micellization temperatures and critical morphological transition temperatures were determined by turbidity measurements and were found to be dependent on the copolymer and water concentrations in the DMF/water system. The morphological changes were only possible if the water concentration in the DMF/water system was low, or else the mobility of the PS blocks would be severely restricted. The driving force for these morphological changes was understood to be mainly a reduction in the free energy of the corona and a minor reduction in the free energy of the interface. Morphological observations at different time periods of isothermal experiments indicated that in the pathway from one equilibrium morphology to another, large compound micelles formed as an intermediate or metastable stage.
在N,N - 二甲基甲酰胺(DMF)/水体系中,观察到了聚合度为962的聚苯乙烯嵌段 - 聚环氧乙烷(PS962 - b - PEO227)胶束因温度诱导而发生的可逆形态变化,其中水是聚环氧乙烷嵌段的选择性溶剂。对于DMF/水体系中含有0.2 wt%共聚物浓度和4.5 wt%水浓度的体系,透射电子显微镜观察到的胶束形态随温度升高从室温下的囊泡变为蠕虫状圆柱体,然后变为球体。在中间温度区域也形成了混合形态。将体系冷却回室温可使囊泡形态再生,表明形态变化是可逆的。在加热和冷却过程中,形态变化未观察到滞后现象。动态光散射表明,胶束的流体动力学半径随温度升高而减小。静态和动态光散射的综合结果支持了形态随温度的变化。通过浊度测量确定了临界胶束化温度和临界形态转变温度,发现它们取决于DMF/水体系中共聚物和水的浓度。只有当DMF/水体系中的水浓度较低时,形态变化才有可能发生,否则聚苯乙烯嵌段的流动性将受到严重限制。这些形态变化的驱动力主要被认为是冠层自由能的降低和界面自由能的少量降低。等温实验不同时间段的形态观察表明,在从一种平衡形态到另一种平衡形态的过程中,大的复合胶束作为中间或亚稳态阶段形成。