聚电解质复合物在表面活性剂水溶液中的溶解机理

聚电解质复合物 ( PEC)因其独特的物理化学性质而受到广泛关注 .对其研究主要集中在其结构及形成的影响因素 ,如聚电解质的分子量 [1,2 ] 、电荷密度、电荷强弱 [1,2 ] 及溶液离子强度 [3,4 ] ,而很少有关于聚电解质复合物溶解性的报道 [5,6 ] .一般认为组成 PEC的聚正离子 ( PC)和聚负离子 ( PA)之间 ,通过离子键形成网状交联结构而不溶于水及有机溶剂 .只有一种特殊的溶剂体系屏蔽溶剂可溶解此类复合物[7,8] .本文报道一类新的聚电解质复合物 :以二苯胺重氮树脂 DR为聚正离子 ,苯乙烯 -马来酸酐碱性水解物 ( PSMNa)为聚负离子的 P…     

酚醛型重氮树脂复合物及自组装超薄膜的制备与应用

不同的高分子链之间可通过次价键而聚集,形成高分子复合物(polymer-polymer omplex).其中,研究最为深入的是基于库仑力的聚电解质复合物(polyelectrolyer complex,PEC)近年来一种继L-B膜技术之后,被称为"层-层”自组装(1ayer-by-layer self-assembly)的技术受到了越来越多的关注自组装技术所组装的分子大多是聚电解质,通常是将带不同电荷的聚电解质分子在水溶剂中交替地组装到片基上,实际上就是在固液界面一层一层地形成聚电解质复合物通过其它弱相互作用如氢键、电荷转移等高分子的自组装基本类似.因此可以说,对高分子自组装的研究基本上是对高分子复合物研究的延伸本论文对重氮树脂-酚醛树脂的感光性复合物以及基于重氮树脂的"层-层”自组装多层膜进行了研究,主要结果如下: 2001年6月通过博士论文答辩     

芳基碘化物[聚(4-乙烯基吡啶)]钯(0)催化下的乙烯基化反应

前文报道了聚[(苯乙烯)联吡啶]钯(0)催化剂在芳基碘化物乙烯基化反应中的应用,其催化剂的活性较高,但连续使用三次后,活性明显降低.本文继续报道能用于芳基碘化物乙烯基化反应的高分子负载钯催化剂的合成和应用.据文献报道能用于芳基碘化物乙烯基化的高分子负载钯催化剂,都是通过多步反应将配体导入聚苯乙烯骨架上合成的,操作比较复杂.为了简化催化剂的制备方法,我们探索了用聚(4-乙烯基吡啶)作高分子载体的可能性.将4 乙烯基吡啶与苯乙烯共聚,加入2%二乙烯基苯作交联剂,生成的共聚物用醋酸钯处理后,加氢化铝锂还原,得到每克含钯7.0mg、氮33.7mg的催化剂,并研究了它在芳基碘化物与苯乙烯、丙烯酸和丙烯酰胺的反应中的催化性能.     

放射标记法研究壳聚糖与牛血清白蛋白的自组装超薄膜

基片在两种带有相反电荷的聚电解质溶液中交替吸附 ,其表面形成致密有序的超薄膜的自组装 (ＥＳＡ ｅｌｅｃｔｒｏｓｔａｔｉｃｓｅｌｆ ａｓｓｅｍｂｌｙ)技术是由Ｄｅｃｈｅｒ及其合作者在 1 991年提出[1] ,由于简单易行 ,从一出现就受到了广大研究者的极大兴趣[2～ 4 ] .对生物材料来说 ,这无疑是一项非常重要且方便的表面改性手段 .因为生物材料在生物体内种植时 ,是否会被机体视为异物 ,关键在于机体与材料表面的相互作用 ,而与材料的本体性质基本无关[5] .因此利用这种技术 ,可对生物材料 ,特别是对那些生物相容性不好的材料表面进行…     

壳聚糖与重氮树脂磺酸盐的感光性超薄膜

由于壳聚糖 ( CS)具有抗菌性、抗病毒性、良好的生物相容性、生物降解性以及容易与金属离子螯合等性质 ,被广泛用于重金属回收 [1～ 3] 、药物释放 [4～ 6] 、伤口覆盖[7,8] 、膜分离 [9,10 ] 、日用化工 [11] 等方面 .近年来 ,人们对壳聚糖以及它的化学改性作了大量的研究 [12～ 14 ] .其中通过化学改性形成壳聚糖聚电解质 ,可与带相反电荷的聚电解质通过静电自组装 ( ESA)获得超薄膜 [15～ 18] .本文尝试用壳聚糖( CS)与二苯胺 - 4-重氮树脂磺酸盐 ( DRS)以及二苯胺 - 4-重氮树脂 ( DR)通过 ESA的方法 ,形成具有感光性的超薄膜 .经 …     

重氮树脂—聚磷酸复合物

带有相反电荷 (通常在侧链 )的聚电解质 ,通过静电相互作用形成的复合物 ,称聚电解质复合物 (ＰＥＣ) .ＰＥＣ已有很多研究[1～ 3] ,也有一些应用的报道[4,5] .重氮树脂 (ＤＲ) ,一种由二苯胺 4 重氮盐与多聚甲醛在浓硫酸中缩合得到的缩聚物[6] ,因侧链带重氮基 ,所以是正离子聚电解质 .它能与各种负离子聚电解质生成感光性的ＰＥＣ ,并可用作光成像体系的感光剂[7,8] .ＤＲ与聚磷酸 (ＰＰＡ)生成重氮基为正离子 ,磷酸基为负离子的复合物 ,这种复合物文献上未有过报道 .本文初步研究了这种复合物的制备与性质 .1　重氮树脂 聚磷酸复合物 (…     

杯芳烃钕/二正丁基镁/六甲基磷酰胺催化4-乙烯基吡啶的均聚及其与苯乙烯的共聚

聚4-乙烯基吡啶[P（4-VP）]是一种功能高分子,由于在吡啶环上有一个碱性的氮原子,它能进一步与酸反应生成各种盐,与卤代烃生成季铵盐以及与金属离子生成配合物,可用作高分子电解质,高分子试剂,高分子功能材料等,因此有不少文献对它的合成进行了报道,合成聚4-乙烯基吡啶及其与苯乙烯（St）的共聚物,除了用丁基锂作引发剂外,过渡金属的Ziegler-Natta催化剂,以及烷基铝和烷基锌等也常被用作催化剂,但用这些催化剂催化所得的聚4-乙烯基吡啶及其与苯乙烯的共聚物产率低,分子量小。     

甲基丙烯酸3-磺酸丙酯钾盐苯乙烯共聚物负离子与N,N,N-三甲基十六烷基溴化铵相互作用研究

聚电解质与表面活性剂相互作用研究已有很多报道[1～4],由于在很多方面与生物膜中脂质体-蛋白质间相互作用相似,从而近年来备受关注[5～6].作为带电荷的水溶性高分子,聚电解质与带相反电荷的表面活性剂分子可以形成规整性非常好的聚电解质表面活性剂复合物.Ａｎｔｏｎｉｅｔｔｔｉ等报道聚丙烯酸与十六烷基三甲基溴化铵(ＣＴＡＢ)形成规整的介规相(Ｍｅｓｏｐｈａｓｅ)聚电解质表面活性剂复合物结构[7],漆宗能等在同一体系既观察到了热致液晶也观察到了溶致液晶[8].在研究甲基丙烯酸3磺酸丙酯钾盐(ＳＰＭＳ)的苯乙烯(Ｓｔ)共聚物(Ｐ(ＳＰＭ…     

强聚电解质对离子型芘衍生物探针的键合

由于芘单线态寿命长 ,单体态发射光谱精细结构对微环境极性敏感 ,在特定的环境下能形成激基缔合物 ,而且可作为非辐射能量转移过程的受体 ,因而被广泛应用于水溶性聚合物的研究 [1～ 3] .芘微溶于水 ,可以作为自由“探针”加入体系探测环境极性的变化与疏水微区的形成 .而离子型的芘衍生物由于良好的水溶性 ,可以同相反电荷的聚电解质发生静电键合 ,最近已经被用来研究聚电解质多层膜的结构 [4 ] .但是芘的离子衍生物同聚电解质键合的规律还不是十分清楚 ,例如聚电解质的电荷密度和化学结构对键合的影响 ,尤其是键合的化学计量关系 ,这对芘…     

一种新型甲壳型液晶高分子的设计与合成

甲壳型液晶高分子是我国科学家最早设计和合成、受到国际学术界广泛关注的一类新型液晶高分子[1～ 6 ] .迄今已合成出 1 0个系列 1 0 0多种甲壳型液晶高分子 ,其中多数以乙烯基氢醌 [7] 、乙烯基对苯二胺 [8] 、乙烯基对苯二甲酸 [9] 和 2 -羟基 - 5-氨基苯乙烯 [10 ] 为关键中间体 .液晶核由 3个苯环以— COO—或— CONH—连接而成 .由于— COO—和— CONH—易与阳离子和阴离子相互作用 ,故已报道的甲壳型液晶高分子都是由自由基聚合反应制得 ,而很难用离子型聚合反应合成 .本文设计合成了一类未见文献报道的小分子液晶化合物 ,由此…     

Interaction of poly(styrene sulfonate) with polycations carrying charges in the chain backbone

The interaction between sodium poly(styrene sulfonate) (NaSS) and side-chain charged polycation polymer (pendent type) or main-chain charged polycation polymer (integral type) has been studied. It was found that the polyion complex (the reaction product of these polyelectrolytes) of pendent–pendent type has an equimolar composition at any mixing ratio of two component polymers. However, a polyion complex of integral–pendent type can form a water-soluble complex with a ratio of [polycation]/[polyanion] = 1/3, in addition to a complex with a equimolar composition. The mechanism of formation of this specific complex is discussed.     

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。     

Polyelectrolyte complexes. II. Specific aspects of the formation of polycation/dye/polyanion complexes

We report on the formation of the polycation/dye/polyanion (PC/D/PA) complexes by the interaction between nonstoichiometric polycation/dye (PC/D) complexes with polyanions. Polycations differed in their content of the (N,N‐dimethyl‐2‐hydroxypropylene ammonium chloride) units in the main chain. Poly(sodium acrylate) (NaPA), poly(sodium 2‐acrylamido‐2‐methylpropane sulfonate) (NaPAMPS) and poly(sodium styrenesulfonate) (NaPSS) were used as polyanions. Crystal Ponceau 6R (CP6R) and Ponceau 4R (P4R) with two or three sulfonic groups were used as anionic dyes. The interaction between nonstoichiometric PC/D complexes and polyanions was followed by UV‐VIS spectroscopy, viscometry, and conductometry measurements. Formation of PC/D/PA complexes takes place mainly by the electrostatic interaction between the polyanion and the free positive charges of the nonstoichiometric PC/D complex. The stoichiometry and the stability of the tricomponent complexes depended on the polycation structure, the structure and molecular weight of polyanion, the dye structure, and the P/D molar ratio. A high amount of the dye was excluded from the complex before the end point when a branched polycation was used. The higher the solubility of the dye the lower the stability of the PC/D/PA complexes. © 1999 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 37: 409–418, 1999     

Counter-ion activity and microstructure in polyelectrolyte complexes as determined by osmotic pressure measurements

We have investigated the activity of counter-ions at 60 degrees C through the osmotic coefficient K in solutions of anionic and cationic polyelectrolyte complexes of variable compositions. For excess of polyanion in the complexes (molar fraction of polycation f < 0.5), K increases as the polyanion is neutralized by the polycation (f getting closer to 0.5). By contrast, for an excess of polycation (f > 0.5), K stays constant or even slightly decreases as the polycation is getting neutralized by the polyanion. This asymmetric behavior depending on the charge of the complexes indicates that the globally negatively charged complexes are homogeneous and can be treated as a single polyelectrolyte of reduced linear charge density. On the other hand, the positively charged complexes show a micro-phase separation between neutral fully compensated microdomains and domains where the excess polycation is locally segregated. These two different microstructures are reminiscent of the coacervation and segregation regimes observed at higher concentrations and salinities, and also of polyelectrolyte complexes with oppositely charged surfactants. This interpretation is supported by two simple predictive models.     

Polymer colloids formed by polyelectrolyte complexation of vinyl polymers and polysaccharides in aqueous solution

The polyelectrolyte complex formed from the polyanion and polycation was studied by turbidimetry, static and electrophoretic light scattering, and elementary analysis. Sodium salts of polyacrylate (PA) and heparin (Hep) were chosen as the polyanion, and hydrochloric salts of poly(vinyl amine) (PVA) and chitosan (Chts) as the polycation. Although these vinyl polymers and polysaccharides have remarkably different backbone chemical structures and linear charge densities, all the four combinations PA-PVA, PA-Chts, Hep-PVA, and Hep-Chts provide almost stoichiometric polyelectrolyte complexes which are slightly charged owing to the adsorption of the excess polyelectrolyte component onto the neutral complex. The charges stabilize the complex colloids in aqueous solution of a non-stoichiometric mixture, and the aggregation number of the complex colloids increases with approaching to the stoichiometric mixing ratio. The mixing ratio dependence of the aggregation number for the four complexes is explained by the model proposed in the previous study.     

Structure of the polyion complex between poly(sodium P-styrene sulfonate) and poly(diallyl dimethyl ammonium chloride)

Stoichiometric and nonstoichiometric polyion complex films were prepared from poly(sodium p-styrene sulfonate) and poly(diallyl dimethyl ammonium chloride). X-ray photoelectron spectroscopy revealed that the ionic groups in the complex are more ionized than in each component polymer. Fluorescence measurements showed that the complex had a main emission peak around 300 nm, whereas the peak for its original polyanion occurred at 324 nm. With the monomer and excimer peaks of the phenyl rings taken to be at 294 and 324 nm, respectively, the ratio of excimer to monomer emission intensities increased in proportion to the mole fraction of polyanion in the observed range 0.44–0.59. There was no discontinuity at the stoichiometric composition. Furthermore, the change in peak position shows that the local aggregation of phenyl groups in the polyanion was destroyed by complexation with the polycation through Coulombic forces. These results, together with the visual observation of the transparency of the films, mean that the mixing between polyanion and polycation chains in the polyion complex is on the molecular level and that this polymer alloy is miscible.     

Assembly of poly(N-isopropylacrylamide)-co-acrylic acid microgel thin films on polyelectrolyte multilayers: Effects of polyelectrolyte layer thickness, surface charge, and microgel solution pH

Temperature- and pH-sensitive poly(N-isopropylacrylamide)?Cco-acrylic acid (pNIPAm-co-AAc) microgels were deposited on glass substrates coated with polyelectrolyte multilayers composed of the polycation poly(allylamine hydrochloride) (PAH) and the polyanion poly(sodium 4-styrenesulfonate) (PSS). The microgel density and structure of the resultant films were investigated as a function of: (1) the number of PAH/PSS layers (layer thickness); (2) the charge on the outer layer of the polyelectrolyte multilayer film; and (3) the pH of microgel deposition solution. The resultant films were studied by differential interference contrast optical microscopy, atomic force microscopy, and scanning electron microscopy. It was found that the coverage of the microgels on the surface was a complex function of the pH of the deposition solution, the charge on the outer layer of the polyelectrolyte thin film and the PAH/PSS layer thickness; although it appears that microgel charge plays the biggest role in determining the resultant surface coverage.     

Structure formation and gelation phenomena in solutions of ternary interpolyelectrolyte complexes

The representative of the new family of mechanically reversible gels is described. The gel is formed by mixing of an aqueous solution of non-stoichiometric interpolyelectrolyte complex of poly (sodium methacrylate) and poly(N-ethyl-4-vinylpyridinium bromide) containing a certain amount of covalent links between oppositely charged polyions, with aqueous solution of poly(potassium vinylsulfate). The gelation mechanism arises to the partial replacement of the electrostatic contacts between the polycation and poly(methacrylate) anion in the original polycomplex with those between the polycation and poly(vinylsulfate) polyanion. The network of the gel is most probably formed by the nodes consisting of covalent links and interpolyelectrolyte double-strand electrostatic clusters, united by poly(sodium methacrylate) tie-chains.     

Studies on the interaction of poly(4-vinylpyridiniumchloride) with poly(sodiumphosphate) in an aqueous solution by conductometry

A reaction between poly(4-vinylpyridiniumchloride) and poly(sodiumphosphate) in the presence and absence of NaCl and NaBr salts was studied in aqueous solution by conductometry. The interaction of polycation and polyanion gave insoluble polyelectrolyte complex which contained polycation and polyanion in unit mole ratio in a salt-free solution. A deviation from stoichiometry was observed at high polyion concentration and in the presence of NaCl and NaBr salts. The resultant complex showed swelling property in different solvent mixtures. A maximum degree of swelling was obtained in the solvent mixture of NaBr + water and NaBr + water + acetone. Furthermore, polyelectrolyte complex sorbed salts from aqueous electrolyte solutions. The sorption of salts increased with increasing salt concentration. © 1996 John Wiley & Sons, Inc.     

New 2-in-1 polyelectrolyte step-by-step film buildup without solution alternation: from PEDOT-PSS to polyelectrolyte complexes

Although never emphasized and increasingly used in organic electronics, PEDOT-PSS (poly(3,4-ethylenedioxythiophene)-poly(styrene sulfonate)) layer-by-layer (lbl) film construction violates the alternation of polyanion and polycation rule stated as a prerequisit for a step-by-step film buildup. To demonstrate that this alternation is not always necessary, we studied the step-by-step construction of films using a single solution containing polycation/polyanion complexes. We investigated four different systems: PEDOT-PSS, bPEI-PSS (branched poly(ethylene imine)-poly(sodium 4-styrene sulfonate)), PDADMA-PSS (poly(diallyl dimethyl ammonium)-PSS), and PAH-PSS (poly(allylamine hydrochloride)-PSS). The film buildup obtained by spin-coating or dipping-and-drying process was monitored by ellipsometry, UV-vis-NIR spectrophotometry, and quartz-crystal microbalance. The surface morphology of the films was characterized by atomic force microscopy in tapping mode. After an initial transient regime, the different films have a linear buildup with the number of deposition steps. It appears that, when the particles composed of polyanion-polycation complex and complex aggregates in solution are more or less liquid (case of PEDOT-PSS and bPEI-PSS), our method leads to smooth films (roughness on the order of 1-2 nm). On the other hand, when these complexes are more or less solid particles (case of PDADMA-PSS and PAH-PSS), the resulting films are much rougher (typically 10 nm). Polycation/polyanion molar ratios in monomer unit of the liquid, rinsing, and drying steps are key parameters governing the film buildup process with an optimal polycation/polyanion molar ratio leading to the fastest film growth. This new and general lbl method, designated as 2-in-1 method, allows obtaining regular and controlled film buildup with a single liquid containing polyelectrolyte complexes and opens a new route for surface functionalization with polyelectrolytes.