硬脂酸聚氧乙烯酯与聚乙烯接枝共聚物的制备与表征

以聚氧乙烯为起始原料,合成了一系列硬脂酸聚氧乙烯酯及其丙烯酸酯,用FTIR和1H NMR测试技术对其结构进行了表征,用最大气泡法测定了其表面张力.以其作为接枝单体,利用反应挤出接枝方法制备了系列功能化聚乙烯,用FTIR确定了接枝共聚物的结构和接枝率;用DSC、接触角测量仪对接枝共聚物的热性能、结晶行为和表面性质进行了测试分析.结果表明,含有不同分子量(200、600、1 000、2 000和6 000)聚氧乙烯的硬脂酸聚氧乙烯酯的表面张力分别为30.19、32.22、35.30、38.39和43.37 mN/m;相应的聚乙烯接枝共聚物的结晶温度分别为109.30、109.08、110.18、109.74和109.74℃,水接触角分别为81.060、70.100、72.25°、76.加.和95.55°.随着聚氧乙烯分子量的增加,表面活性剂的表面活性降低;聚乙烯接枝共聚物的结晶温度高于线形低密度聚乙烯(LLDPE,T.=104.95℃),且其亲水性得到改善(纯聚乙烯的水接触角103°).     

丙烯酸聚氧乙烯酯单体接枝聚乙烯共聚物的制备与表征

采用含α-双键的4种不同结构的聚氧乙烯型单体:丙烯酸聚氧乙烯酯(PAA)、丙烯酸端甲氧基聚氧乙烯酯(PEA)、甲基丙烯酸聚氧乙烯酯(PMA)和甲基丙烯酸端甲氧基聚氧乙烯酯(PMEM)接枝改性线性低密度乙烯(LLDPE)和低分子量聚乙烯(LMPE).采用核磁共振波谱及红外光谱分析了接枝共聚物的结构,并研究了接枝单体中聚氧乙烯基团对接枝共聚物性能的影响.相同单体浓度下4种单体的接枝效率大小顺序为PAAPEAPMAPMEM.对产物流变性能的研究结果表明随着接枝率的增加,单体复合黏度和剪切变稀行为增加;示差量热扫描结果显示了接枝率较低时接枝单体起到异相成核作用而加速结晶.为了进一步观察接枝单体对聚乙烯链段微观结构的影响,通过偏光显微镜观察发现LMPE为短棒状结构,而接枝LMPE通过支链极性基团的相互作用而形成星形或树枝状的微胶束结构.接触角测试表明,与LLDPE相比,高接枝率的LMPE改善亲水性的效果更好.     

聚乙烯亚胺接枝聚对二氧环己酮的合成与表征

以聚乙烯亚胺(PEI)为大分子引发剂,辛酸亚锡为催化剂,引发对二氧环己酮(PDO)单体开环聚合,通过graft from法制备了聚乙烯亚胺接枝聚对二氧环己酮接枝共聚物(PEI-g-PPDO).通过FTIR、1H-NMR、1H-13C-HMQC等对共聚物的分子结构进行了表征.共聚产物的接枝链长度、亲疏水链段含量等可以通过反应物中单体的含量进行有效调控;用DSC对共聚物的热性能和结晶性能研究表明,接枝链段长度越大、PPDO链段含量越高,共聚物的结晶性能也越好.采用芘探针法初步研究了共聚物在水中的胶束化行为,PEI-g-PPDO接枝共聚物在水中可以形成较稳定的聚集体.     

两亲磁性高分子微球的合成与表征

在Fe3O4磁流体存在下 ,通过苯乙烯与聚氧乙烯大分子单体 (MPEO)分散共聚制备两亲磁性高分子微球 .研究了聚氧乙烯大分子单体对微球粒径的影响 .用扫描电子显微镜 (SEM)、原子力显微镜 (AFM)表征了磁性微球的粒径、表面形貌以及表面粗糙度 ,用傅立叶红外光谱 (FTIR)鉴定了共聚物的结构 .随着聚合物中聚氧乙烯大分子单体含量的增加 ,微球表面的粗糙度增加 ,通过改变共聚物中MPEO的含量 ,可以得到含有 0 4～ 3 5mg g羟值的两亲磁性高分子微球     

接枝共聚物聚苯乙烯－g－聚氧乙烯的微相分离形态研究

 本文利用透射电子显微镜技术，以两性接校共聚物聚苯乙烯－ｇ－聚氧乙烯为研究对象，研究了接枝共聚物的微相分离形态结构，发现聚苯乙烯－ｇ－聚氧乙烯能形成微相分离结构，微区的形状和尺寸与共聚物的组成和侧链长度有关．文中还讨论了嵌段共聚物和接枝共聚物在形成微相分离结构时的共性和个性．     

聚甲基丙烯酸甲酯接枝聚氧乙烯在甲苯中的聚集态结构

两亲接枝共聚物;胶束;聚甲基丙烯酸甲酯接枝聚氧乙烯在甲苯中的聚集态结构     

以混合表面活性剂为模板可控合成MCM-48和MCM-41分子筛

利用阳离子和三嵌段共聚物混合表面活性剂为模板,在水热条件、碱性介质中可控合成出MCM-48和MCM-41分子筛。在固定P123(聚氧乙烯-聚氧丙烯-聚氧乙烯三嵌段共聚物):TEOS(正硅酸乙酯)(物质的量的比)为0.01875的体系中,调节CTAB(十六烷基三甲基溴化铵)∶TEOS(正硅酸乙酯)物质的量比值m,当m在0.12~0.13范围合成出MCM-48分子筛;当m在0.04~0.08范围合成出MCM-41分子筛。通过XRD,TEM,N2物理吸附,IR等方法进行了表征。结果表明:聚氧乙烯-聚氧丙烯-聚氧乙烯三嵌段共聚物(P123)的加入可以更大程度地降低合成介孔材料所需阳离子表面活性剂的用量;可控合成的介孔材料具有高比表面积、高度有序的孔道结构、较集中的孔径分布。     

接枝共聚物聚苯乙烯－g－聚氧乙烯的微相分离形态研究

本文利用透射电子显微镜技术，以两性接校共聚物聚苯乙烯－ｇ－聚氧乙烯为研究对象，研究了接枝共聚物的微相分离形态结构，发现聚苯乙烯－ｇ－聚氧乙烯能形成微相分离结构，微区的形状和尺寸与共聚物的组成和侧链长度有关．文中还讨论了嵌段共聚物和接枝共聚物在形成微相分离结构时的共性和个性．     

阳离子碳氢/碳氟表面活性剂与中性高聚物相互作用的研究

研究了阳离子碳氢表面活性剂十二烷基三烷基溴化铵[C12H25N(CnH2n＋1)3Br, n＝1, 2, 3, 4]和阳离子碳氟表面活性剂F[CF(CF3)CF2O]2CF(CF3)CONH(CH2)3N(C2H5)2CH3I (FCI-2)分别与中性高聚物聚氧乙烯(PEO, 分子量20000)和聚氧乙烯-聚氧丙烯三嵌段共聚物[(EO)76(PO)29(EO)76, F68]的相互作用. 结果表明, 所用的碳氢阳离子表面活性剂与PEO和F68均无相互作用, 但碳氟阳离子表面活性剂FCI-2与PEO和F68均具有明显的相互作用, 而且F68与FCI-2的相互作用强于PEO与FCI-2体系. 结果也初步表明碳氟表面活性剂与高聚物的相互作用强于碳氢表面活性剂-高聚物体系.     

反应型非离子表面活性剂的制备及其组成和结构

以丙烯酸(AA)与硬脂酸单甘油酯(GMS)、油酸单甘油酯(A300)或油酸单山梨糖醇酐酯(Span 80)为起始物, 对甲苯磺酸为催化剂, 对苯二酚为阻聚剂, 制备了三类含有1-烯键的反应型表面活性剂. 通过反应体系中AA 的加料量及其残留量, 计算得到丙烯酸的转化率为91%以上, 制备的反应型非离子表面活性剂的收率达到80%以上. 用红外光谱(FTIR)、核磁共振氢谱(1H NMR)和质谱对反应产物的组成和结构进行了表征, 确认获得了三类目标产物. 将这三类表面活性剂作为流滴剂与聚乙烯发生接枝反应后, 提高了聚乙烯的结晶温度, 降低了水在聚烯烃膜表面的接触角, 解决了聚乙烯农用棚膜的流滴期短的问题.     

Synthesis of poly(styrene-graft-ethylene oxide) by ethoxylation of amide group containing styrene copolymers

Graft copolymers containing poly(ethylene oxide) side chains on a polystyrene backbone have been synthesized. Styrene copolymers synthesized by free radical mechanism and containing between 5 and 15 mol % acrylamide or methacrylamide were used as backbones. The amide groups in the copolymers were ionized by using potassium tert-butoxide or potassium naphthalene, and grafting was achieved by utilizing the amide anions as initiator sites for the polymerization of ethylene oxide in 2-ethoxyethyl ether at 65°C. The graft copolymers were characterized with respect to molecular weight and composition using elemental analysis, NMR, gel permeation chromatography, IR, and viscosity measurements. The size of the side chains were between 600 and 2000 g/mol. GPC results from a hydrolyzed graft copolymer sample suggest a narrow size distribution for the poly(ethylene oxide) grafts. Solution properties of the graft copolymers were investigated in different toluene/methanol mixtures. The intrinsic viscosities of the graft copolymers were found to depend primarily on the poly(ethylene oxide) content rather than the graft density or the poly(ethylene oxide) chain length. © 1993 John Wiley & Sons, Inc.     

Synthesis and characterization of model block-graft copolymers via anionic polymerization: Introduction of poly(isoprene) and poly(ethylene oxide) as graft chains

New architectural graft copolymers were prepared, that is, the graft chains were situated in terminal or center position of the backbone chain. These graft copolymers were termed block-graft copolymers. Two different block-graft copolymers were prepared from a “grafting onto” process and a “grafting from” process via living anionic polymerization. These backbone chains are poly(styrene), and the graft chains are poly(isoprene) and poly(ethylene oxide). The polymers were characterized by GPC measurements, osmometry, and ultracentrifugation. The block-graft copolymers formed fine microphase separation structures. It was a morphological feature that an apparent volume fraction of the graft to the backbone might be higher than the real volume fraction.     

阴离子聚合制备聚乙烯-g-聚氧化乙烯接枝共聚物

聚烯烃 (聚乙烯 ,聚丙烯等 )的化学改性一直是科学研究和实际生产的一个热点 ,改性过的聚烯烃可以广泛应用到高分子共混物和复合材料中 .在众多聚烯烃中 ,聚乙烯产量最大 ,但因其惰性也最难于化学改性 .我们采取的改性方法是在聚合物中引入反应性基团 ,可以在温和条件下进行有选择的而且高效的化学改性 .由于两亲性共聚物可用作乳液聚合和悬浮聚合中的表面活性剂及稳定剂 ,塑料的表面改良剂和聚合物的共混相容剂等[1,2 ] ,因此人们对该共聚物的研究越来越多 .过去 ,多数两亲性共聚物的研究局限于聚苯乙烯 (ＰＳ)和聚氧化乙烯 (ＰＥＯ)接枝共…     

Preparation and physical properties of novel nonionic surfactants and their grafting copolymers with linear low density polyethylene (LLDPE)

Three nonionic surfactants, S1, S2, and S3 and their acrylates, AS1, AS2, and AS3, were synthesized with poly(ethylene oxide) and diols such as glycol, 1,6‐hexanediol, and 1,10‐decanediol as the main starting materials. Their chemical structures were characterized by means of Fourier transform infrared (FTIR) spectroscopy and ¹H NMR. The surface activity and surface tension (γ) of S1, S2, and S3 were evaluated by a drop weight method. The surface tension was found to decrease with the length of the lipophilic spacer in the molecular chains (γ_S1 < γ_S2 < γ_S3). AS1, AS2, and AS3 were adopted as functionalizing monomers and grafted onto linear low density polyethylene (LLDPE) with a melt reactive extrusion procedure. The graft degrees of LLDPE were determined by FTIR. Three grafted LLDPE samples with grafting degrees of 1.16% (AS1), 0.82% (AS2), and 0.71% (AS3) were prepared. Thermal and rheological properties of grafted LLDPE samples were studied with differential scanning calorimetry and a rotational rheometer. Crystallization rates of grafted LLDPE were faster than that of plain LLDPE at a given crystallization temperature because graft chains could act as nucleating agents. The isothermal crystallization behavior of grafted LLDPE was in accordance with the Avrami model only in the first stage, and deviated from the model with an increase in the crystallization time. Shear thinning at high shear rates and shear thickening at low shear rates were observed for the grafted LLDPE. © 2004 Wiley Periodicals, Inc. J Polym Sci Part B: Polym Phys 43: 314–322, 2005     

P(MMA-co-MAh)-g-mPEG的合成及环境敏感性

采用偶合接枝法在甲基丙烯酸甲酯(MMA)和马来酸酐(MAh)无规共聚物上接枝不同含量的聚乙二醇单甲醚(mPEG), 合成具有pH敏感和温度敏感的两亲接枝共聚物P(MMA-co-MAh)-g-mPEG, 并对其进行了红外光谱和核磁共振波谱表征. 通过紫外-可见分光光度计测量了接枝共聚物水溶液的透光率, 结果表明, 接枝聚合物的水溶液呈现低临界溶解温度(LCST), 其LCST值对环境pH值和无机盐等因素敏感, 并可通过控制亲水侧链含量来调节.     

Poly(vinyl chloride)–poly(ethylene oxide) block copolymers: Synthesis and characterization

Poly(vinyl chloride)-poly(ethylene oxide) block copolymers have been synthesized in solution and emulsion. The polymers were made by first synthesizing macroazonitriles through the reaction of 4,4′-azobis-4-cyanovleryl chloride with hydroxy-terminated poly(ethylene oxide) of varying molecular weights. These macroazonitriles had molecular weights in the range of 3000–88,000 and degrees of polymerization from 5 to 24. Thermal decomposition of the azolinkages in the presence of vinyl chloride monomer yielded block copolymers containing form 2 to 20 wt % poly(ethylene oxide). The structures of the block copolymers were characterized by spectrometric, elemental and molecular weight analyses. The possibility of some graft polymerization occurring via free-radical extraction of a methylene hydrogen from the poly(ethylene oxide) was considered. Polymerization of vinyl chloride with an azonitrile initiator in the presence of a poly(ethylene oxide) yielded predominately homopolymer with some grafted poly(vinyl chloride).     

含氟两亲接枝共聚物的制备及其与牛血清蛋白作用的研究

用端基反应法合成了对乙烯基苄基的聚乙二醇大分子单体,将该大分子单体与甲基丙烯酸六氟丁酯共聚,合成了一种含氟两亲接枝共聚物.利用1H-NMR1、9F-NMR、GPC对大分子单体和两亲接枝共聚物进行了表征.表面张力法测定了两亲接枝共聚物的临界胶束浓度,发现随着共聚物中含氟链段含量的增加,其临界胶束浓度降低.采用荧光光谱研究了含氟两亲接枝共聚物与牛血清蛋白(BSA)的相互作用,结果表明由于含氟链段疏水力的作用,含氟两亲接枝共聚物能与牛血清蛋白发生相互作用使其荧光增强,随着含氟两亲接枝共聚物浓度和共聚物中含氟链段含量的增加,荧光增强幅度加大.通过透射电子显微镜(TEM)和激光光散射粒度仪(PCS)测试发现,当BSA加入到含氟两亲接枝共聚物的胶束溶液后,所得胶束的粒径和粒径分布变大,共聚物胶束由规整的实心核壳结构变为囊泡状核壳结构.     

Micellization and Adsorption Parameters of Poly(Propylene Oxide)/Poly(Ethylene Glycol) Block and Graft Copolymers in Aqueous Medium

This work aims to measure the adsorption and micellization parameters of new water soluble nonionic amphiphilic block and graft copolymers based on hydrophilic poly (ethylene glycol) (PEG) and hydrophobic poly (propylene oxide) (PPO) at ambient temperature and normal atmospheric pressure. The chemical composition and molecular weights of the prepared copolymers were determined from ¹H NMR analyses. The surface properties of the prepared surfactants were determined by measuring the surface tension at different temperatures. The surface tension, critical micelle concentration, and surface activities were determined at different temperatures. Surface parameters such as surface excess concentration, the area per molecule at interface and the effectiveness of surface tension reduction were determined from the adsorption isotherms of the prepared surfactants. Some thermodynamic data for the adsorption and micellization process were calculated and are discussed.     

Preparation of thin surface layers by grafting of PEO

We have developed a two‐stage process to graft poly(ethylene oxide) (PEO) onto a silica surface. In the first stage the adsorption of an anchor reactive polymer to the surface is carried out, and in the second stage the grafting of compatibilizing macromolecular tails is performed via the reactions of functional groups of the polymer anchored. Random copolymers of styrene and maleic anhydride (SM) were chosen as reactive anchoring polymers. The kinetics of adsorption of SM from dilute solutions onto the silica surface as well as the grafting of PEO to SM macromolecules adsorbed was experimentally investigated by null ellipsometry. A model of the structure at the surface is proposed.     

Crystallization behavior, thermal property and biodegradation of poly(3-hydroxybutyrate)/poly(ethylene glycol) grafting copolymer

The poly(3-hydroxybutyrate)(PHB)/poly(ethylene glycol)(PEG) grafting copolymer was successfully prepared by PHB and acrylate groups ended PEGM using AIBN as initiator. The crystallization behavior, thermal stability and environmental biodegradability of PHB/PEG grafting copolymers were investigated with differential scanning calorimetry (DSC), Thermogravimetric analysis (TGA), wide angle X-ray diffraction (WAXD), scanning electron microscopy (SEM), and Biodegradation test in vitro. In the results, all the grafting copolymers were found to show the X-ray diffraction arising from the PHB crystal lattice, while none of the PEG crystallized peaks could be found even though the graft percent reached 20%. This result indicated that PEG molecules were randomly grafted onto PHB chain. The thermal properties measured by DSC showed that the melting temperature(T_m) and glass transition temperature (T_g) were both shifted to lower temperature with the graft percent increasing, and this broadened the narrow processability window of PHB. According to TGA results, the thermal stability of the grafting copolymers is not changed compared to pure PHB. From the biodegradation test, it could be concluded that degradation occurred gradually from the surface to the inside and that the degradation rate could be adjusted by the PEG grafting ratio. In another words, the biodegradation profiles of PHB/PEG grafting copolymer can be controlled. These properties make PHB/PEG grafting copolymer have promising potential applications especially in agriculture fields.