Division of Physical Chemistry, Department of Chemistry, Lund University, P.O. Box 124, SE-22100 Lund, Sweden.
Langmuir. 2011 Jan 18;27(2):592-603. doi: 10.1021/la104256g. Epub 2010 Dec 17.
The redissolution of water-insoluble polyion-surfactant ion complexes by added excess of surfactant has systematically been investigated in experimental and theoretical phase equilibrium studies. A number of stoichiometric polyion-surfactant ion "complex salts" were synthesized and they consisted of akyltrimethylammonium surfactant ions of two different alkyl chain lengths (C(12)TA(+) and C(16)TA(+)) combined with homopolyions of polyacrylate of two different lengths (PA(-)(25) and PA(-)(6000)) or copolyions of acrylate and the slightly hydrophobic nonionic comonomers N-isopropylacrylamide (PA(-)-co-NIPAM) or N,N-dimethylacrylamide (PA(-)-co-DAM). The complex salts were mixed with water and excess alkyltrimethylammonium surfactant with either bromide or acetate counterions (C(n)TABr or C(n)TAAc). Factors promoting efficient redissolution were (i) very short polyions, (ii) a large fraction of NIPAM or DAM comonomers, and (iii) acetate, rather than bromide, as the surfactant counterion. Added C(12)TAAc gave an efficient redissolution of C(12)TAPA(25) but virtually no redissolution of C(12)TAPA(6000). A very efficient redissolution by added C(12)TAAc was obtained for PA(-)-co-NIPAM with 82 mol % of NIPAM. The C(12)TAPA-co-NIPAM/C(12)TAAc/H(2)O ternary phase diagram closely resembled the corresponding diagram for the much-studied pair cationic hydroxyethyl cellulose-(sodium) dodecyl sulfate. The simple Flory-Huggins theory adopted for polyelectrolyte systems successfully reproduced the main features of the experimental phase diagrams for the homopolyion systems, including the effect of the surfactant counterion. The efficient redissolution found for certain copolyion systems was explained by the formation of soluble polyion-surfactant ion complexes carrying an excess of surfactant ions through an additional hydrophobic attraction.
水不溶性聚离子-表面活性剂离子配合物通过加入过量的表面活性剂重新溶解已在实验和理论相平衡研究中得到系统地研究。合成了一些化学计量的聚离子-表面活性剂离子“复合盐”,它们由两种不同链长的烷基三甲基铵表面活性剂离子(C(12)TA(+)和 C(16)TA(+))与两种不同长度的聚丙烯酸均聚物(PA(-)(25)和 PA(-)(6000))或丙烯酸盐和稍微疏水的非离子共聚单体 N-异丙基丙烯酰胺(PA(-)-co-NIPAM)或 N,N-二甲基丙烯酰胺(PA(-)-co-DAM)的共聚物组成。将复合盐与水和带溴化物或乙酸盐反离子(C(n)TABr 或 C(n)TAAc)的过量烷基三甲基铵表面活性剂混合。促进有效重溶解的因素有:(i)非常短的聚离子,(ii)NIPAM 或 DAM 共聚单体的很大一部分,以及(iii)乙酸盐,而不是溴化物,作为表面活性剂反离子。加入 C(12)TAAc 可以有效地重溶解 C(12)TAPA(25),但实际上不能重溶解 C(12)TAPA(6000)。加入 C(12)TAAc 可以非常有效地重溶解 NIPAM 摩尔分数为 82%的 PA(-)-co-NIPAM。C(12)TAPA-co-NIPAM/C(12)TAAc/H(2)O 三元相图与研究得更多的阳离子羟乙基纤维素-(钠)十二烷基硫酸盐非常相似。用于聚电解质体系的简单 Flory-Huggins 理论成功地复制了均聚物体系实验相图的主要特征,包括表面活性剂反离子的影响。对于某些共聚物体系发现的有效重溶解可以通过形成带有过量表面活性剂离子的可溶性聚离子-表面活性剂离子配合物来解释,这是通过额外的疏水吸引力实现的。
