疏水化水溶性聚电解质的增粘作用

疏水化水溶性聚电解质是一种大分子主链或侧链上含有少量疏水基团的新型水溶性功能高分子材料,在水溶液中具有良好的耐盐耐温增粘作用和贮存稳定性。对该类聚电解质的特殊增粘作用及分子结构、聚合物浓度、无机盐、机械剪切作用、ｐＨ、温度、表面活性剂、老化时间及与其他疏水化水溶性聚合物作用等影响因素进行了综述。     

聚皂凝胶在溶液中的溶胀-消溶胀研究

聚皂是一类疏水改性的聚合物电解质,在其大分子结构中既带有亲水基团又带有疏水基团．通过一定程度的交联,可获得聚皂水凝胶．与近年来颇受关注的智能聚合物水凝胶一样,聚皂凝胶也表现出了相当的环境敏感特性．一般来说,聚合物水凝胶的ｐＨ敏感特性取决于分子链上所含...     

重氮树脂型聚离子复合物

高分子化合物沿分子链(主链和侧链)排列多量可离解基团(每个链节可有1～2个)称聚电解质或聚离子^[1]。聚电解质在水中可离解成两部分,若离解后,聚合物链带负电荷,称聚阴离子电解质或聚负离子;若带正电荷,称聚阳离子电解质或聚正离子。     

疏水改性聚丙烯酰胺溶液的分子模拟

设计了几种不同的非离子型改性聚丙烯酰胺(HM-PAM)和阴离子型改性聚丙烯酰胺(HM-HPAM). 通过分子动力学模拟(MD)方法研究了在聚合物链上加入不同疏水改性单体对提高聚丙烯酰胺耐盐性的影响, 考察了盐浓度对疏水改性聚丙烯酰胺的回旋半径(R_g)、 特性黏数([η])、 径向分布函数(RDF)和均方位移(MSD)的影响以及聚合物的微观结构与特性黏数之间的关系. 研究结果表明, 引入疏水改性单体后, 改性聚丙烯酰胺具有较好的耐盐性. 通过研究非键作用与氢键相互作用可知, 体系中溶质和溶剂间的相互作用及氢键作用越弱, 溶液的特性黏数越大. O-H原子对的RDF结果表明, 聚合物链的伸展与聚合物链及官能团间的相互作用有关. 当RDF峰较弱时, 聚合物链与水的作用越弱, 越有利于聚合物链保持舒展状态, 溶液的特性黏数也就越大. 另外, 从聚合物链的MSD曲线发现, 聚合链的移动性与特性黏数呈负相关.     

具有反聚电解质溶液行为的两性聚合物

大分子链上同时含有正负电荷基团且其数目相等的两性聚合物，具有独特的反聚电解质溶液行为和广阔的应用前景。本文就其合成、溶液特性及应用进行了概述。     

氟碳端基聚合物合成及其表面吸附性能

综述了近十年来氟端基聚合物的合成,表征及其在表面吸附行为的研究成果。通过含有氟烷基的引发剂或终止剂在活性阴离子聚合反应或自由基聚合反应中使聚合物接上氟端基。已经成功地利用活性阴离子聚合反应合成了氟端基聚苯乙烯,通过含氟自由基引发烯类单体（如丙烯酸,乙烯硅等）可在相应聚合物链上引入氟端基,另外,聚合物的化学改性方法也可将氟基团接在聚合物链端（如氟基聚氧乙烯,氟端基聚合物具有的表面活性,当水溶液中或聚     

电荷密度和疏水性对疏水改性聚丙烯酰胺与牛血清蛋白相互作用的影响

对比研究了牛血清蛋白(BSA)与部分水解的未改性聚丙烯酰胺(PAM-AA)、疏水改性聚丙烯酰胺(PAM-C12)和含有丙烯酸基团的疏水改性聚丙烯酰胺(PAM-C12-AA)之间的相互作用.等温滴定量热实验结果表明,除PAM-C12外,其他聚合物与BSA的结合焓均为放热,随AA含量的增加,放热焓值增大.与PAM和PAM-C12相比,PAM-C12-AA能够诱导BSA二级结构和微环境的明显变化,表明疏水性和电荷密度均对聚合物与BSA相互作用有重要影响.另外,不同浓度的PAM-C12-AA与BSA的作用方式不同,当聚合物的浓度略高于临界胶束浓度(CMC)时,由于聚合物的量较少,BSA分子改变其构型从而最大程度地与聚合物结合;当聚合物的浓度远高于CMC时,更多的聚合物链结合到BSA分子的正电荷"patch"上,PAM-C12-AA与BSA的紧密聚集体利于BSA二级结构的稳定.     

粘度法研究疏水改性聚丙烯酸与Np7.5的相互作用

研究了氟基团改性和氟碳、碳氢基团同时改性的聚丙烯酸（HM－PAA）以及参与聚合物（PAA）与非离子表面活性剂Np7.5分别在稀溶液和亚浓溶液下的相互作用对特性粘数和Brookfield表观粘度的影响。结果表明,PAA与Np7.5无明显作用,而M－PAA在Np7.5达到一定浓度后,由于Np7.5参与了疏水缔合,特性粘数和表观粘度发生了明显变化。稀溶液中,氟碳基团较多的聚合物出现了链构象的伸展。亚浓溶液中,疏水改性聚合物的粘度都有先上升后下降的变化,但氟碳含量较多的变化更强烈。     

表面活性剂对污泥脱水性能影响的机理研究:Gemini表面活性剂与聚电解质相互作用的分子动力学模拟

表面活性剂可以与污泥表面的胞外聚合物(EPS)吸附形成胶束,释放出自由水和结合水,从而达到改善污泥脱水性能的目的.本文采用粗粒化的分子动力学模拟方法,研究了Gemini表面活性剂与EPS形成复合物的过程和结构.聚电解质链的亲疏水性对吸附过程有显著影响,亲水聚电解质链与Gemini表面活性剂吸附的主要驱动力为静电吸引,Gemini表面活性剂头基吸附在链上,尾链朝向溶剂;疏水聚电解质链与Gemini表面活性剂吸附过程由静电作用与疏水作用共同促进,Gemini表面活性剂以平行于聚电解质链的构型存在.Gemini表面活性剂联结基团长度对吸附过程的影响甚微;聚电解质链的电荷密度对亲水聚电解质链的吸附产生协同作用,对疏水聚电解质链的吸附不产生作用.     

疏水缔合聚丙烯酰胺的合成及溶液性能研究

水溶性疏水缔合聚合物是在聚合物亲水主链上引入极少量疏水基团(一般小于2ｍｏｌ%)而形成的一种新型水溶性聚合物[1]。由于这类聚合物具有独特的流变性能,因而备受学术界和工业界关注。目前已作为涂料增稠剂[2]和流变改性剂[3]得到了应用,而通过在部分水解聚丙烯酰胺(ＨＰＡＭ)的亲水主链上引入少量疏水单体而形成的疏水缔合聚丙烯酰胺(ＨＡＰＡＭ)则可望克服ＨＰＡＭ耐温、耐盐性差的缺陷[4]而作为新一代水溶性聚合物材料用于油气开采作业[5,6]。由于亲水单体和疏水单体的不相容性,通常通过在反应溶液中加入表面活性剂使亲水单体和疏水单体…     

PROPERTIES OF DILUTE SOLUTIONS OF HYDROPHOBICALLY MODIFIED POLY (4-VINYL PYRIDINE) (POLYSOAPS)

Hydrophobically modified poly(4-vinyl pyridines) by alkyl bromides arekinds of polysoap similar to the surfactant. Properties of dilute solutions were studiedthrough the viscosity measurements in pure water and NaCl solutions. In aqueous solu-tions of polysoaps hydrophobic interaction can be attributed to aggregation of hydrophobicgroups of the polysoap main chains. The hydrophobic groups of polysoap can aggregate toform hydrophobic microdomains (micelles) in aqueous solution. This is a compact confor-mation. The formation of such microdomains is a process of dynamic equilibrium.     

荧光法研究含长链烷基聚丙烯酰胺的疏水微区结构

荧光法研究含长链烷基聚丙烯酰胺的疏水微区结构邱星屏，张雪蓉，丁马太（厦门大学化学系，厦门，３６１００５）关键词萘酚，聚丙烯酰胺，疏水微区聚丙烯酰胺作为增粘剂和絮凝剂，已用于石油开采、水处理等领域［１］．在聚丙烯酰胺链上引进少量疏水侧基，可显著地改变其...     

Design of three-dimensional, millimeter-scale models for molecular folding.

This communication describes the fabrication of three-dimensional structures of organic polymers using principles of design inspired by protein folding. The structures consist of rigid polyhedral components with dimensions of a few millimeters ("microdomains"), representing alpha-helical and beta-sheet secondary structures, connected with flexible linkers representing loops or turns. These structures were fabricated from polyurethane using photolithographic and soft lithographic techniques. The surfaces of the microdomains were patterned into hydrophobic and hydrophilic regions, and a hydrophobic photocurable liquid (serving both as lubricant and adhesive) was selectively precipitated onto the hydrophobic areas. The unfolded structures were suspended in water and agitated by tumbling. Self-assembly occurred through coalescence of the thin films of hydrophobic liquid, and was caused by minimization of the free energy of the interface between the liquid adhesive and the water. The self-assembled structures were locked in place by curing the adhesive with UV light. These results demonstrate the use of concepts abstracted from the study of proteins-including attractive hydrophobic interactions, shape complementarity, and conformational constraint-in the self-assembly of complex, three-dimensional structures on the millimeter scale.     

Elaboration of modelized surfaces with well defined microtopochemistry–localization of adsorbed proteins

Using microphotolithographic techniques, we have been able to devise silica surfaces bearing two types of microdomains with an average width of 40μm. One of the microdomain types was silanized in order to make them hydrophobic. Fourier transform-infrared (FTIR) and Auger electron spectroscopies (AES) were used to check the presence of the expected chemical groups on the modified silica surface. Silica and silanized surface morphology was studied using Scanning Force Microscopy (SFM). Wetting properties were investigated. Protein adsorption studies were performed using diluted human decalcified plasma. Attention was focused on the topographic distribution of the adsorbed molecules in order to establish a correlation between the protein behaviour and the specific chemistry of each type of microdomain.     

Aggregation Behavior of Mono-endcapped Hydrophobically Modified Poly(sodium acrylate)s in Aqueous Solution

Titration microcalorimetry and steady-state fluorescence spectroscopy have been used to study the aggregation of mono-endcapped hydrophobically modified poly(sodium acrylate)s in aqueous solution. Polymers with molecular weights varying between 800 and 31,700 were synthesized by radical polymerization using an initiator and chain transfer agent. The resulting polymers form hydrophobic microdomains in aqueous solutions. The following conditions were applied: no salt and pH 5 and 9, respectively; 1 M sodium citrate and pH 9. At pH 5 the critical aggregation concentration (CAC, the concentration at which microdomains are formed) increases with increasing molecular weight of the polymers. The concentration range for aggregation is about 0.2-2.4 mM. At pH 9 the carboxylic acid groups are deprotonated and electrostatic repulsions are introduced; therefore the concentration for aggregation rises to about 80 mM. Interestingly, in case of polymers having M(n)<1400 the CAC decreases with increasing molecular weight due to a counterion-concentration gradient toward the hydrophobic microdomain. Near the microdomain the counterion binding is increased, reducing the electrostatic repulsions and allowing for lower aggregation concentrations. In the presence of 1 M sodium citrate this anomalous trend is suppressed to a large extent; since the overall counterion binding is increased and the CAC is lower. The concentration for aggregation is then in the same range as at pH 5 in the absence of salt. Copyright 2000 Academic Press.     

Amphiphilic cholesteryl-bearing carboxymethylcellulose derivatives: self-assembly and rheological behaviour in aqueous solution

The self-assembly of amphiphilic cholesteryl-bearing carboxymethylcellulose derivatives (CCMCs) from individual molecules to self-aggregates, in addition to their rheological behaviour in aqueous solution were investigated. The conformations of the individual CCMC individual molecules and self-aggregates, and the microstructures of CCMC self-aggregates were characterized using the static and dynamic light scattering analyses, and the steady fluorescence technology. The results showed that the individual CCMC chains became compact, and aqueous NaCl solution changed from an approximate θ solvent to a bad one when the number of hydrophobic cholesteryl groups increased. The CCMC self-aggregates exhibited as compact spheres. The microstructural characterization indicated that one CCMC self-aggregate consisted of multiple individual CCMC molecules and hydrophobic microdomains, and multiple cholesteryl groups self-associated into one hydrophobic microdomain. The atomic force microscopy images of CCMC self-aggregates in phase mode showed that the multiple interior hydrophobic phase separation regions were surrounded by hydrophilic polysaccharide chains, providing an evidence for multiple hydrophobic microdomains in one self-aggregate. The rheological analysis proved that the CCMC self-aggregates were a microgel, in which the associations of cholesteryl groups provided multiple cross-linking points in the polymer network. The microgel solutions displayed a unique thixotropy and a shear thinning behaviour.     

Fluorescent probes for detection of amphiphilic polymer hydrophobic microdomains: A comparative study between pyrene and molecular rotors

 Cationic amphiphilic polymers (e.g. polyvinylpyridinium bromides and polyvinylimidazo-lium bromides) adopt a compact coiled form in aqueous solutions. In the case of former polymers, the resulting hydrophobic microdomains are evidenced only by fluorescence spectroscopy if a molecular rotor (DMAC) is used as a fluorescent probe, while the behaviour of the latter can be studied in aqueous solution by using both types of fluorescent probes, i.e., pyrene and the molecular rotor. The purpose of the present investigation deals with a comparative study between the magnitude of the local viscosity and the polarity of the hydrophobic microdomains generated by poly(3-hexadecyl-1-vinylimidazolium bromide) in an aqueous medium using pyrene and DMAC as fluorescent probes. Moreover, the results are compared with the data obtained with micelles of conventional surfactants such as the homopolymer repetitive unit model and CTAB. Received: 3 June 1996 Accepted: 29 September 1996     

Interactions of a hydrophobically modified polymer with oppositely charged surfactants

The interaction of a hydrophobically modified anionic polymer (PMAOVE) with a cationic surfactant (DTAB) was studied using a multi-technique approach: turbidity, surface tension, and viscosity measurements, as well as EPR (5-doxyl stearic acid) and fluorescence (pyrene) probe techniques were used. In the investigated pH range (4-10), the cationic surfactant headgroups interact with the anionic carboxylic groups of the polymer backbone. In addition, nonpolar interactions of the surfactant chains with the n-octyl chains of PMAOVE stabilize the PMAOVE-DTAB complexes. Charge neutralization of the anionic polymer by the cationic surfactant leads to precipitation of the PMAOVE-DTAB complex at a certain DTAB concentration range. Further addition of DTAB causes a charge reversal of the complex and, subsequently, resolubilization of the precipitate. At an acidic pH (pH = 4), a second precipitation was observed, which is probably caused by conformational changes in the PMAOVE-DTAB complex. This second precipitate can be resolubilized by further addition of surfactant. At a neutral and basic pH, this second precipitation is absent. EPR analysis indicates that the surfactants form an ordered structure at the extended polymer chain at a neutral and basic pH, whereas at an acidic pH, a less ordered surfactant layer is formed on the coiled polymer with more hydrophobic microdomains.     

Thickening and Associating Behavior in Aqueous Solutions of a Terpolymer with Poly(ethylene oxide) Side Chains

A water-soluble terpolymer (PAVA) was synthesized by aqueous free radical copolymerization technique using acrylamide(AM), sodium 2-acrylamido-2-methylpropane-sulphonate (NaAMPS) and a macromonomer: p-vinylbenzyl-terminated octylphenoxy poly(ethylene oxide) (VPEO, degree of polymerization: 10). The remarkable intermolecular hydrophobic associations were formed in water and a brine solution for this polymer, which resulted in a good thickening effect, resistance to salt and salt-thickening. The hydrophobically associating microstructures of PAVA in aqueous solutions were measured by the fluorescent probe and scanning electron microscope. As polymer concentration was increased in water and brine solutions, the associating strength and non-polarity of hydrophobic microdomains increased remarkably. However, at the polymer concentrations higher than 0.20 g/dL, the non-polarity of hydrophobic microdomains tended to remain constant, and the I ₁/I ₃ value changed slightly in 0.5 g/dL NaCl. The continuous associating structures were formed by the expanded polymer chains in brine solutions, as well as in water. As the NaCl concentration increased, the non-polarity of associating microstructures increased slowly, but the compact degree of these microstructures increased.     

Fluorescence Spectroscopic Study for Interaction of Pyrene-Labeled Poly(2-acrylamido-2-methylpropane Sulfonates)s Bearing Octadecyl Group with Nonionic Surfactant Molecules

The interactions of the hydrophobically random-modified and end-capped polyanions with a nonionic surfactant were investigated by fluorescence spectroscopy of the labeled Py in the polyanions. The results revealed that the complex formation between these polyanions and the nonionic surfactant took place with two steps; the first step is the insertion of the surfactant molecules into hydrophobic microdomains formed from the polyanions, and the second step is the disruption of the hydrophobic microdomains due to binding the surfactant molecules to the hydrophobic groups of the polyanions. The position of the hydrophobic groups covalently introduced in the polyanions affects the polyanion-surfactant complex formation.