PREPARATION OF HIGH DENSITY POLYETHYLENE/POLYETHYLENE-BLOCK-POLY(ETHYLENE GLYCOL)COPOLYMER BLEND POROUS MEMBRANES VIA THERMALLY INDUCED PHASE SEPARATION PROCESS AND THEIR PROPERTIES

High density polyethylene （HDPE）/polyethylene-block-poly（ethylene glycol） （PE-b-PEG） blend porous membranes were prepared via thermally induced phase separation （TIPS） process using diphenyl ether （DPE） as diluent. The phase diagrams of HDPE/PE-b-PEG/DPE systems were determined by optical microscopy and differential scanning calorimetry （DSC）. By varying the content of PE-b-PEG, the effects of PE-b-PEG copolymer on morphology and crystalline structure of membranes were studied by scanning electron microscopy （SEM） and wide angle X-ray diffraction （WAXD）. The chemical compositions of whole membranes and surface layers were characterized by elementary analysis, Fourier transform infrared spectroscopy-attenuated total reflection （FTIR-ATR） and X-ray photoelectron spectroscopy （XPS）. Water contact angle, static protein adsorption and water flux experiments were used to evaluate the hydrophilicity, antifouling and water permeation properties of the membranes. It was found that the addition of PE-b-PEG increased the pore size of the obtained blend membranes. In the investigated range of PE-b-PEG content, the PEG blocks could not aggregate into obviously separated domains in membrane matrix. More importantly, PE-b-PEG could not only be retained stably in the membrane matrix during membrane formation, but also enrich at the membrane surface layer. Such stability and surface enrichment of PE-b-PEG endowed the blend membranes with improved hydrophilicity, protein absorption resistance and water permeation properties, which would be substantially beneficial to HDPE membranes for water treatment application.

Synthesis and Surface Tension Properties of Polyethyleneimine-Polyethylene Oxide Block Copolymers

This paper describes the synthesis, surface tension and dispersancy properties of block copolymer nonionic surfactants comprised of polyethyleneimine (PEI) and polyethylene oxide (PEO) blocks of selected lengths. These block copolymers were prepared by a three step synthetic sequence. Firstly, PEO glycol was converted to its dimethanesulphonylester (dimesyl) derivative by reacting with methanesulphonyl chloride. Then a tri block polymer was prepared by the ring opening polymerization of 2 methyl 2 oxazoline (MeOZO) with the dimesyl PEO derivative. Lastly, linear PEI blocks were obtained by subsequent hydrolysis and purification. 1H NMR spectra confirmed the structures of the intermediate, final products and their purities (>99%). The utility of these block copolymers is described in terms of their surface tension and clay dispersancy measurements as a function of copolymer chain and block length.

Block Copolymer Networks Composed of Poly(ε-caprolactone) and Polyethylene with Triple Shape Memory Properties

In this contribution, we reported a novel synthesis of block copolymer networks composed of poly(ε-caprolactone)(PCL) and polyethylene(PE) via the co-hydrolysis and condensation of α,ω-ditriethoxylsilane-terminated PCL and PE telechelics. First, α,ω-dihydroxylterminated PCL and PE telechelics were synthesized via the ring-opening polymerization of ε-caprolactone and the ring-opening metathesis polymerization of cyclooctene followed by hydrogenation of polycyclooctene. Both α,ω-ditriethoxylsilane-terminated PCL and PE telechelics were obtained via in situ reaction of α,ω-dihydroxyl-terminated PCL and PE telechelics with 3-isocyanatopropyltriethoxysilane. The formation of networks was evidenced by the solubility and rheological tests. It was found that the block copolymer networks were microphase-separated. The PCL and PE blocks still preserved the crystallinity. Owing to the formation of crosslinked networks, the materials displayed shape memory properties. More importantly, the combination of PCL with PE resulted that the block copolymer networks had the triple shape memory properties, which can be triggered with the melting and crystallization of PCL and PE blocks. The results reported in this work demonstrated that triple shape memory polymers could be prepared via the formation of block copolymer networks.

基体性质对HDPE/SEBS共混物脆韧性转变的影响——验证Leibler增韧模型

为了研究高密度聚乙烯(HDPE)基体性质对共混物脆-韧转变的影响,本文通过熔融共混的方法制备了苯乙烯-乙烯/丁烯-苯乙烯嵌段共聚物(SEBS)/HDPE共混物,利用扫描电子显微镜观察了分散相的粒子尺寸及分布,明确了基体性质与临界粒子间距(ID_c)之间的定量关系。结果表明,随着基体HDPE熔体质量流动速率的减小,共混物发生脆-韧转变时需要的临界弹性体质量分数越小,分散相SEBS的粒子尺寸越小,越有利于共混物脆-韧转变的发生。同时,聚合物共混物的脆-韧转变与基体材料断裂强度(σ_(B))、屈服强度(σ_(Y))有很大的关系,(σ_(B)/σ_(Y))^(2)越大,ID_(c)越大,共混物的脆-韧转变越容易发生,验证了Leibler增韧模型的正确性,并通过线性拟合得到相邻两个微裂纹平均距离(ξ*)和系数(C)。

PA1211-b-PEG弹性体的制备与性能

采用熔融缩聚法,以十一碳二元酸、十二碳二元胺和聚乙二醇(PEG)为反应原料,钛酸四丁酯为催化剂,制备了5种不同相对分子质量聚酰胺链段的PA1211-b-PEG弹性体。通过红外光谱(FTIR)表征了PA1211-b-PEG的化学结构,采用广角X射线衍射(XRD)、差示扫描量热分析(DSC)、热失重分析(TG)、扫描电子显微镜(SEM)和力学性能测试等,研究了硬段分子量对PA1211-b-PEG弹性体的结晶形态、熔融和结晶温度、热稳定性、断裂面微观形貌和力学性能的影响。研究结果表明,双端羧基的PA1211预聚体与双端羟基的PEG发生了酯化反应,成功制备了PA1211-b-PEG弹性体。同时,随着硬段分子量的减小,PA1211-b-PEG弹性体的熔融温度由179.5℃减小至172.2℃、结晶温度由152.3℃减小至145.6℃,热分解温度逐渐向低温区移动;软段和硬段间存在显著的微相分离。另外,随着硬段相对分子质量的减小,PA1211-b-PEG弹性体的拉伸强度由35.5 MPa减小至14.8 MPa、拉伸模量减小了约640 MPa,冲击强度由6.7 kJ/m^(2)增大至11.9 kJ/m^(2),断裂伸长率增大了约200%。

分子量差异及组分含量对PS/CBC共混体系的相容性及聚集态结构的影响

共混体系中两相的分子量差异及组分含量直接影响共混体系相容性及共混物聚集态结构,从而对共混物的性能产生影响。为探究不同基体含量及不同分子量差异对共混物结构与性能所产生的影响,指导材料的开发和应用,制备了不同分子量及不同组分的聚乙烯基环己烷-b-聚乙烯-b-聚乙烯基环己烷(CBC)/聚苯乙烯(PS)共混物,运用差示扫描量热仪(DSC)及原位同步辐射广角衍射(WAXD)、小角散射(SAXS)作为表征手段,对共混体系的相容性,相分离行为以及聚集态结构进行研究,并对材料进行了光学性能测试。研究发现,PS与CBC中聚乙烯基环己烷(PVCH)嵌段具有一定的相容性,PS与CBC中聚乙烯(PE)嵌段相容性较差。PS进入到PVCH嵌段中会破坏其聚集态结构,增大链间距离,较少量PS进入到PE嵌段中,会使得PE嵌段的结晶能力上升,较多量PS进入到PE嵌段时,会使得PE结晶能力下降,并且会使PE的链间距离变大。共混体系中CBC含量在10%以下时,观察不到明显的相分离行为。同时,研究发现分子量差异对于二者的相容性影响是极为明显的,对于同一种PS(PG383M)而言,其与分子量差异较小的CBC1325的相容性要明显优于分子量差异较大的CBC8210,从而形成更均一的相区使材料的雾度降低并使透过率得到提升。

IMPROVING THE PROPERTIES OF HDPE BASED SEPARATORS FOR LITHIUM ION BATTERIES BY BLENDING BLOCK WITH COPOLYMER PE-b-PEG

To improve the performances of HDPE-based separators, polyether chains were incorporated into HDPE membranes by blending with poly（ethylene-block-ethylene glycol） （PE-b-PEG） via thermally induced phase separation （TIPS） process. By measuring the composition, morphology, crystallinity, ion conductivity, etc, the influence of PE-b-PEG on structures and properties of the blend separator were investigated. It was found that the incorporated PEG chains yielded higher surface energy for HDPE separator and improved affinity to liquid electrolyte. Thus, the stability of liquid electrolyte trapped in separator was increased while the interfacial resistance between separator and electrode was reduced effectively. The ionic conductivity of liquid electrolyte soaked separator could reach 1.28 ×10^-3 S.cm^-1 at 25℃, and the electrochemical stability window was up to 4.5 V （versus Li^＋/Li）. These results revealed that blending PE-b-PEG into porous HDPE membranes could efficiently improve the performances of PE separators for lithium batteries.

CPE增容PVC／SBS共混体系的研究

通过冲击试验、应力－应变试验、动态力学分析（ＤＭＡ）、扫描电镜（ＳＥＭ）及光学显微镜观察，研究了ＣＰＥ增容的ＰＶＣ／ＣＰＥ－ＳＢＳ共混物的性能与形态结构之间的关系。实验结果表明，ＣＰＥ对ＰＶＣ与ＳＢＳ共混体系有很好的增容作用，ＣＰＥ与ＳＢＳ在一定组成范围内对ＰＶＣ增韧具有协同效应，大幅度地提高共混物的抗冲击性能。

LDPE/SBS共混物改性沥青体系的反应共混行为

利用应变控制流变仪对LDPE/SBS共混物改性沥青过程中的反应共混行为进行了初步研究,考察了交联剂及温度对反应共混行为的影响,分析了反应共混特性。结果表明,在交联剂存在下,LDPE/SBS共混物中的SBS与交联剂发生了化学反应,引起了转矩的升高。在温度高于120℃时开始反应,反应速度随温度的升高而加快。当温度超过230℃时,转矩在反应开始后先升后降,可能是聚合物发生降解所造成的。同时,增加交联剂用量有利于提高反应速度。

SEBS对交联聚乙烯的电性能及水树抑制的影响

电缆绝缘材料的抗水树性能可以通过化学改性和物理改性来提高。为此将苯乙烯-乙烯-丁烯-苯乙烯嵌段共聚物(SEBS)及马来酸酐接枝的苯乙烯-乙烯-丁烯-苯乙烯嵌段共聚物(SEBS-g-MA)分别与低密度聚乙烯(LDPE)进行熔融共混,经过热压成型后制得了XLPE/SEBS和XLPE/SEBS-g-MA两种交联聚乙烯共混物,研究了SEBS以及SEBS-g-MA对交联聚乙烯(XLPE)的抗水树性能的影响,结果发现SEBS与SEBS-g-MA具有良好的抗水树效果,共混物XLPE/SEBS的水树长度随着SEBS质量分数的增加而减小,共混物XLPE/SEBS-g-MA在SEBS-g-MA的质量分数为4.76%时水树的长度最短。另外还表征了XLPE/SEBS和XLPE/SEBS-g-MA共混物的形态以及介电性能,结果显示XLPE/SEBS和XLPE/SEBS-g-MA共混物具有良好的绝缘性能。

两亲性二嵌段共聚物MPEG_(44)-b-Phe的合成及其在水溶液中的自组装

利用光气法,以三光气和苯丙氨酸为原料,合成了苯丙氨酸酸酐(b-Phe-NCA).用端氨基聚乙二醇单甲醚(MPEG-NH2)作大分子引发剂,引发b-Phe-NCA开环聚合,合成了不同分子量的聚乙二醇单甲醚-聚(L-苯丙氨酸)(MPEG44-b-Phe)AB型二嵌段共聚多肽.利用IR1、H-NMR、GPC对共聚物结构进行了表征.利用TEM研究了二嵌段共聚多肽MPEG44-b-Phe50及MPEG44-b-Phe7在水溶液中的自组装形态,结果表明合成出的两亲性二嵌段共聚物在水溶液中自组装形成胶束,随着嵌段共聚物中亲水嵌段含量的增高,共聚物溶水性增强,其在水溶液中的自组装形态更加均一.

新型茂钛催化剂合成聚乙烯-b-间规聚苯乙烯嵌段共聚物的研究Ⅰ.嵌段共聚合反应

以五甲基茂基三苄氧基钛 [Cp Ti(OBz) 3]为主催化剂、改性甲基铝氧烷 (mMAO)为助催化剂 ,进行乙烯与苯乙烯的嵌段共聚合反应 .讨论了乙烯预聚温度、预聚时间、主催化剂的浓度、Al(mMAO) Ti摩尔比、苯乙烯的浓度以及外加三异丁基铝 (TIBA)等条件对共聚反应的影响 .发现适宜的共聚反应条件为 ,预聚温度为40℃ ;主催化剂的浓度为 6 6 7× 10 - 4 mol L ;铝钛摩尔比为 2 0 0 .共聚反应的催化效率随预聚时间的延长而降低 ;嵌段共聚物中苯乙烯链节含量随苯乙烯的浓度的增加而增加 ;

紫杉醇自组装核壳型纳米胶束的制备与性能

本文合成了聚乙二醇-聚谷氨酸苄酯（polyethylene glycol-polybenzyl-L-glutamate，PEG-PBLG）两亲嵌段共聚物，并采用超微透析法制备了紫杉醇／PEG-PBLG核壳型纳米胶束。通过高效液相色谱测定了胶束的载药量及药物包封率；采用动态光散射法测定了胶束的粒径及分布；通过体外试验研究了紫杉醇／PEG-PBLG胶束的释药特性；采用四噻唑蓝法考察了紫杉醇／PEG-PBLG胶束的体外细胞毒性；通过裸鼠的抑瘤试验评价了紫杉醇胶束对人肝癌细胞的疗效。结果表明，PEG-PBLG胶束能包埋疏水性药物紫杉醇；紫杉醇／PEG-PBLG胶束的粒径为80—265nm，且随着载体共聚物PBLG嵌段相对分子质量的升高而增大；紫杉醇／PEG-PBLG胶束的体外释放具有缓释特性；当紫杉醇浓度大于20μg·mL^-1时，紫杉醇／PEG-PBLG胶束的细胞毒性低于相应浓度的紫杉醇／聚氧乙烯蓖麻油注射剂（P〈0．05），紫杉醇／PEG-PBLG胶束具有与紫杉醇／聚氧乙烯蓖麻油注射剂相似的抑制肿瘤作用。综上所述，紫杉醇／PEG-PBLG纳米胶束具有较均匀的粒径及粒径分布、缓释特性、低毒和较好的抗肿瘤作用。

线形PEO嵌段物的合成研究

利用低分子量的聚乙二醇 ( PEG4 0 0 )与 CH2 Cl2 在 KOH作用下合成氧亚甲基连接的嵌段共聚物 ,对反应条件进行研究 ,并结合电化学方法——电渗析除尽了经常规处理方法 (溶解、过滤、沉淀 )所不能除尽的微量杂质 KOH,得到了彻底纯化产物 ,利用凝胶色谱仪 GPC4 10确定其平均分子量为 10 5,IR、1H- NMR表征其以 [CH2 O( CH2 CH2 O) ]n为重复单元的结构。

酯－酰胺交换反应对聚对苯二甲酸乙二酯／聚酰胺66共混体形态结构和流变性能的影响

采用不同的共混方式－溶液法、熔融法Ⅰ（简单机械共混）和熔融法Ⅱ（存在酯－酰胺交换反应）将聚对苯二甲酸乙二酯（ＰＥＴ）与聚酰胺６６（ＰＡ６６）共混，研究了共混体的形态结构和流变性能，探讨了对甲苯磺酸（ＴｓＯＨ）催化下的酯－酰胺交换反应和ＰＥＴ／ＰＡ６６共混体系的相容性．

聚己内酯，聚乙二醇及其嵌段物的结晶行为

聚己内酯，聚乙二醇及其嵌段物的结晶行为高家武，段跃新，王身国，邱波（北京航空航天大学材料科学与工程系北京１０００８３）（中国科学院化学研究所北京）关键词聚己内酯，聚乙二醇，嵌段共聚物，结晶度，结晶动力学聚己内酯（ＰＣＬ）作为生物降解材料，无毒、无副作...

LDPE/SEBS/CB电致形状记忆复合材料的结构与性能

通过熔融共混法将热塑性弹性体氢化苯乙烯-丁二烯-苯乙烯嵌段共聚物(SEBS)和低密度聚乙烯(LDPE)制成形状记忆聚合物(SMP)材料;在SMP材料中填充导电炭黑(CB),制成具有电致形状记忆特性的LDPE/SEBS/CB复合材料。通过SEM、DSC分析和力学性能、电性能、记忆性能测试,研究了CB含量对电致SMP材料结构与性能的影响。结果表明:当CB含量达到20%时,LDPE/SEBS/CB复合形状记忆材料的体积电阻率降至103Ω·cm左右,CB的导电网络趋于稳定;并且LDPE/SEBS/CB(2:2:1)复合形状记忆材料的形状固定率约90%,常温拉伸和高温拉伸时均表现出较高的形状回复率(约90%),拉伸模量约170MPa,拉伸强度约9.5MPa,断裂伸长率约400%。

防腐卷材用热熔压敏胶的研制

以100份国产SIS和SBS热塑弹性体为主体原料,配合增粘剂萜烯树脂100～120份、增塑剂环烷油40～60份、填料0～10份、防老剂1份等研制出热熔压敏胶,用于聚乙烯防腐卷材与管道的粘接。该胶粘接聚乙烯卷材的剥离强度达6.ON·cm^(-1),粘接不锈钢的剥离强度达9.0N·cm^(-1),既能保证与被保护材料的有效粘合,又解决了聚乙烯卷材反粘难解卷的问题。

PPQ-b-PEG刚柔嵌段共聚物的合成及热稳定性

以聚乙二醇单甲醚、丁二酸酐、4-氨基苯乙酮、5-乙酰基-2-氨基二苯甲酮为原料合成了以聚苯基喹啉(PPQ)为硬段、聚乙二醇(PEG)为软段的"刚棒—线团"两嵌段共聚物PPQ b PEG,通过IR、1HNMR对其结构进行了表征,并对PPQ b PEG嵌段共聚物的热稳定性进行研究,结果表明:PPQ b PEG(d)的热稳定性高,PPQ b PEG起始的分解温度为250℃,在250～400℃失重很少,其失重率小于5%,在400～600℃才迅速失重,到620℃时彻底分解。

温度对PVB/Pluronic F127/PEG200体系的动态流变学行为的影响

采用动态流变仪研究了温度对聚乙烯醇缩丁醛(PVB)/Pluronic F127/聚乙二醇(PEG)200共混体系的动态流变学性能的影响。结果表明,体系的黏度随剪切频率的增大而减小,表现出假塑性流体的特征;复数黏度、动态储能模量、动态损耗模量随温度的升高而降低;非牛顿系数和损耗因子随温度的升高而增大。体系在温度高于140℃时表现出均相聚合物体系的流变行为,低于140℃时动态储能模量明显偏离了均相体系低频末端的标度规则。