超支化聚醚的支化度对玻璃化转变温度的影响

聚合物的分子结构对聚合物性能影响很大.支化度不同的同种聚合物,必须通过不同的催化体系合成,很难得到既具有相近分子量又具有不同支化度的系列聚合物样品,因此对聚合物性能与支化度的依赖关系的研究报道不多.     

用凝胶渗透色谱测定聚合物中的支化度

本文在Ambler报导的测定聚合物中支化度的工作基础上,提出了支化度的计算方法和电子计算机计算程序,可用ALGOL-60语言在国产DJS-6电子计算机上计算。讨论了支化模型、短链支化和长链支化分布函数等对计算结果的影响,确定了该方法可以相对比较镍系顺式聚丁二烯中的支化度。     

环氧硅烷室温交联丙烯酸酯共聚无皂水溶胶的研究 Ⅰ.环氧硅氧烷微乳液的制备

介绍了丙烯酸酯共聚无皂水溶胶的室温交联剂——环氧硅氧烷(KH-560)的乳化方法。研究了乳化剂类型、用量以及KH-560含量对微乳液性能的影响。结果表明，OP-10具有较好的乳化效果；当ω(OP-10)＝5％、ω(KH-560)＝40％时，微乳液稳定性最佳。微乳液加人无皂水溶胶中制得的交联乳液(用量为5％)室温放置6个月后性能无明显变化，干燥涂膜的交联度达到93％，而且具有较好的耐水、耐溶剂性能(水中溶胀度降低了83％，在甲苯中由原来的溶解变为溶胀115％)。     

含氟环氧树脂杂化纳米二氧化硅超疏水材料的制备与性能

目前超疏水材料的制备方法大都存在着制备工艺复杂的缺点。 本文采用传统自由基聚合方法,以甲基丙烯酸缩水甘油酯(GMA)和苯乙烯(St)为单体,合成具有交联性的前驱聚合物P(GMA-r-St)。 再用三氟乙酸(TFA)对其进行接枝改性,制备含氟环氧聚合物P(GMA-r-St)-g-TFA。 利用γ-氨丙基三乙氧基硅烷(KH-550)改性纳米二氧化硅(SiO₂),对其进行傅里叶变换红外光谱(FTIR)、热重(TG)表征。 氨基改性的纳米二氧化硅与含氟环氧聚合物混合制备的超疏水改性材料,棉织物表面经其浸泡,可快速构建超疏水结构。 通过改变改性纳米颗粒的含量,探究其构筑的棉织物的疏水性能和耐溶剂性能。 研究结果表明,经浸泡改性的棉织物,水接触角为160°,耐溶剂性时间为130 min,具备很好的耐溶剂性。 该方法可广泛应用于多种基底材料表面的疏水改性。     

生漆/氨基硅氧烷/环氧桐油复合涂料的 制备与性能研究

以生漆为原料,先采用γ-氨乙基氨丙基三甲氧基硅烷(AATMS)与漆酚的酚羟基发生醇解反应,再通过AATMS的氨基与环氧桐油的环氧基发生开环反应,得到了一种复合涂料。该涂料的干燥成膜过程是在漆酶作用下,通过空气自氧化聚合得到高度交联的聚合膜。固定AATMS用量为生漆质量分数10%不变,讨论了环氧桐油用量对生漆的物理机械性能的影响,结果发现环氧桐油用量为生漆质量分数的30%时,漆膜的性能最佳,柔韧性、耐冲击性、硬度、附着力分别提高到2mm、40kg·cm-1、6H和1级。利用红外光谱分析(FT-IR)证实了复合涂膜的结构。利用热分析(TG-DTG)研究了复合涂膜和生漆涂膜的热稳定性,结果表明复合涂膜比生漆涂膜的热稳定性高。研究测试了复合涂膜和生漆涂膜的耐溶剂性能、耐化学介质性能和耐老化性能,结果表明复合涂料的漆膜比生漆涂膜性能都大幅提升。     

用GPC-级分特性粘数法表征高顺式-1,4聚丁二烯的长链支化

本文在Ambler方法和kraus方法的基础上,用GPC-级分特性粘数法来测定聚合物的长链支化度,能同时以g_i、λ_i、G_i、m_i、支化重量百分数等支化参数来表征聚合物的支化分布、支化程度和支化含量等;得到了相应的计算gi、λi、[η]_i等有关的计算公式和计算方法;还研制成了以光导纤维为冷光源的高精度光电自动计时毛细管粘度计和60小时内恒温精度优于±5×10~(-4)℃的超级恒温水浴,使计时精度达到≤±4×10~(-3)秒;并以国产和进口的镍系顺丁橡胶为例,讨论了分子量和支化度多分散性之间的某些关系;从而确定了该法比较合理地、全面地相对比较聚合物的长链支化度。     

星形SIS嵌段共聚物的动态力学性能

本文报导了用粘弹谱仪对组成相同、支链分子量相同而支化度不同的,以及支化度相同、支链分子量不同的系列星形SIS嵌段共聚物的测试结果,实验发现:支链分子量是影响各相玻璃化转变温度和动态杨氏模量E′的主要因素,支化度对各相玻璃化温度影响很小,但是对E′影响是明显的。     

窄分子量分布茂金属短链支化聚乙烯结晶动力学

本工作用DSC方法对三种不同支化度的茂金属短链支化聚乙烯的等温、非等温结晶行为进行了研究 .样品为乙烯和己烯 1的共聚物 ,短支链主要为正丁基 ,分子量Mw =2 0 ,0 0 0 ,Mw/Mn<1 15 ,支化度 (每10 0 0C中CH3 数目 )分别为 1 6、10 4、40 .实验结果表明 ,茂金属短链支化聚乙烯结晶方式Ⅰ Ⅱ转变温度随支化度增加而降低 ,分别为 119 8℃、115 9℃、113 3℃ ;同时支链的存在降低了二次成核速率 ,增大了方式Ⅰ的结晶范围 ,总的结晶速度随支化度增大而减小     

高度支化共聚物的均方回转半径和支化度的关系

对于聚合物的均方回转半径和支化度的关系, 过去鲜有定量研究, 这是由于具有不同支化度的系列同种聚合物样品较难合成之故. 1982年, Kricheldorf等[1]报道了AB2和AB型单体的共缩聚反应, 这种反应可以方便地通过调节AB2和AB型单体的比例来控制产物的支化度.     

可交联LB膜的研究(Ⅱ)——5-[2-(4-己基偶氮苯)苯氧乙基-L谷氨酸酯和5-(6-己二醇肉桂酸酯)基-L-谷氨酸酯共聚物的合成、LB膜性质及光交联反应的研究

将聚｛5－[2－（4－己撑）苯基偶氮乙基]｝（P2AB6－LG）体系中部分引入带肉桂酸酯基的侧链,合成了5－[2－（4－己基偶氮苯）苯氧乙基－L－谷氨酸酯和5－（6－己二醇肉桂酸酯）基－L－谷氨酸酯共聚物（PG2AB6-co-Cin）,研究了它的LB膜行为,并通过光交联来改进膜的耐溶剂稳定性。     

Photopatternable thin films from silyl hydride containing silicone resins and photobase generators

The photopatternability of various silyl hydride containing organosilicone resins containing the photobase generators N‐methylnifedipine or O‐(2‐nitrobenzyl)‐N‐octyl carbamate have been examined, with the goal of identifying potential photopatternable compositions with high thermal stability after cure. Two different categories of silicone resins have been prepared from combinations of diphenylsiloxane and methyl and hydrogen silsesquioxane units and a combination of phenyl and hydrogen silsesquioxane monomer units. The photobase generators were incorporated into these resins at concentrations up to 10 weight percent. UV‐irradiation of micrometer thick silicone resin‐photobase films through a photomask, under an air atmosphere, yielded micrometer scale features after development. Photopatternable compositions have been identified with photosensitivities of less than 50 mJ/cm2. The photopatterning process is believed to proceed by base‐catalyzed reaction of resin‐based silanol groups with neighboring silyl hydride groups to yield thermally stable siloxane crosslinks. Copyright © 1999 John Wiley & Sons, Ltd.     

高密度聚乙烯的熔融支化及其对性能的影响木

在引发剂过氧化二异丙苯、二官能度单体新戊二醇二丙烯酸酯和自由基活性调控剂二甲基二硫代氨基甲酸锌的存在下,使高密度聚乙烯进行熔融支化反应.研究表明,转矩曲线上的反应峰顶对应最佳反应时间,由此获得了凝胶量低的长链支化高密度聚乙烯.熔融支化反应使聚乙烯的分子量分布变宽,其支化程度随单体含量的增加而增大,呈现出更加明显的剪切变稀行为;长链支化结构的引入使改性聚乙烯的结晶度降低,长支链的成核作用使起始结晶温度增加,球晶尺寸明显减小.改性聚乙烯的支化程度和大分子拓扑结构的变化对耐环境应力开裂性能的影响显著,当单体含量超过0.6 phr时,长链支化分子形态从类似不对称星形转变为梳形,使得高密度聚乙烯的耐环境应力开裂时间产生突变,达1000 h以上,同时强度、模量和冲击韧性均得到明显提高.     

Characterization of linear low-density polyethylene: Cross-fractionation according to copolymer composition and molecular weight

The structure of ethylene copolymers modified by α-olefins has become an area of intense investigation since the successful commercialization of so-called linear low-density polyethylene (LLDPE) resins. The molecular structure of a series of typical commercial LLDPE copolymers was investigated and compared to LDPE and HDPE. The commercial LLDPE resins studied contained about 7% by weight of butene-1. The resins were fractionated according to short-chain branching content by a technique called temperature rising elution fractionation. Size exclusion chromatography, x-ray diffraction, ¹³C nuclear magnetic resonance, intrinsic viscosity, and differential scanning calorimetry were used to fully characterize the whole polymers as well as fractions of a selected LLDPE resin. A broad set of data was assembled in this work to investigate the short-chain branching, long-chain branching, and the molecular-weight distribution of these commercial resins. The melting behavior of the LLDPE resins was found to be strikingly different from that of LDPE and HDPE. The broad and multimodal melting envelope of the LLDPE resins was found to be due to a broad and multimodal short-chain branching distribution. No significant long-chain branching was found in the LLDPE resins. The short-chain branching was found to decrease with the increase of molecular weight in a typical commercial LLDPE resin. The unique physical properties of these resins are certainly strongly controlled by the expression of the distinctive heterogeneous comonomer incorporation in the solid-state morphological structure. The physical and mechanical properties of these materials should be ultimately understandable on the basis of the unique morphology which results from the extremely heterogeneous incorporation of modifying α-olefin in these commercial LLDPE resins.     

Alumina‐Incorporated Polyesteramide from Non‐Edible Seed Oils

To improve the physico‐mechanical and chemical resistance properties, lower the curing temperature of annona squamosa and pongamia glabra seeds oils based polyesteramides [ASPEA, PGPEA], as well as to convert the non‐edible seed oils into value added products, their respective alumina‐incorporated polyesteramides resins [Al‐ASPEA, Al‐PGPEA] have been synthesized. The resins and their coatings have been tested for their chemical, physico mechanical and chemical/corrosion resistance properties. These properties were compared among the prepared resins and with that of previously reported alumina filled linseed polyesteramide [Al‐LPEA]. It was observed that Al‐PGPEA‐71, which has the highest amount of oleic acid chains, shows the best physico‐mechanical and chemical resistance properties.     

Morphological explanation of the extraordinary fracture toughness of linear low density polyethylenes

The fracture toughness of commercial linear low-density polyethylenes (LLDPE) has been found to be extraordinarily high relative to commercial low-density (LDPE) and high-density (HDPE) polyethylenes in previously reported investigations. The present investigation shows that this extraordinary fracture toughness cannot be explained by differences in molecular structure variables, such as molecular weight, long-chain and short-chain branching, fractional crystallinity, and comonomer content. Instead, the presence of a second soft phase, which was extractable with a weak solvent, in a hard semicrystalline matrix was discovered by morphological investigations of LLDPE resins. This second phase arises from the extreme compositional heterogeneity of the copolymers which comprise these LLDPE resins. No evidence for a similar morphological entity was found in LDPE and HDPE resins. This finding provides persuasive evidence that this very-low-crystallinity second phase performs a function similar to that of the rubberlike second phase in other high impact resins and, thus, leads to the observed extraordinary fracture toughness of LLDPE resins. Evidence for the nature and existence of this second phase is given from temperature-rising elution fractionation and scanning electron microscopy investigations.     

Estimating Slow Crack Growth Performance of Polyethylene Resins from Primary Structures such as Molecular Weight and Short Chain Branching

Summary: Molecular weight and short chain branching (SCB) data experimentally obtained by SEC-FTIR are combined into a single, primary structural parameter (PSP2) and used to rapidly screen the slow crack growth resistance of a variety of polyethylene resins. Our results show that PSP2 values obtained for resins made using different catalysts (both dual and single catalyst systems) and hence, different polymer architectures, correlate well with results obtained from several short-term tensile tests. The development of PSP2, as well as the qualitative and quantitative predictive ability of this parameter are presented and discussed.     

Epoxy resins from rosin acids: synthesis and characterization

A series of multifunctional cycloaliphatic glycidyl ester and ether epoxy resins were synthesized by reaction of condensed rosin acid‐formaldehyde resins with epichlorohydrin. The chemical structure of the produced resins was determined by IR and ¹H‐NMR analysis. The molecular weight of the produced resins was determined by gel permeation chromatography (GPC). A series of poly‐ (amide‐imide) hardeners were prepared from condensation of Diels–Alder adducts of rosin acid‐maleic anhydride and acrylic acid with triethylene tetramine and pentaethylene hexamine. These amines were also condensed with Diels–Alder adducts of rosin ketones. The curing exotherms of the produced epoxy resins with poly(amide‐imide) hardeners were investigated. The data of mechanical properties, solvent and chemical resistance indicate the superior adhesion of the cured epoxy resins. Copyright © 2004 John Wiley & Sons, Ltd.     

Environmental stress cracking resistance of polyethylene: The use of CRYSTAF and SEC to establish structure–property relationships

Nineteen commercial high‐density polyethylene resins made with different polymerization processes and catalyst types were analyzed by high‐temperature size exclusion chromatography and crystallization analysis fractionation. The information obtained with these characterization techniques on the polymer chain structure was correlated to environmental stress cracking resistance. Environmental stress cracking resistance increases when the molecular weight and concentration of polymer chains that crystallize in trichlorobenzene between 75 and 85 °C increase. Polymer chains present in this crystallization range are assumed to act as tie molecules between crystal lamellae. © 2000 John Wiley & Sons, Inc. J Polym Sci B: Polym Phys 38: 1267–1275, 2000     

Radiation resistance of pyridine type anion exchange resins for spent fuel treatment

The resistance against radiation of the tertiary pyridine resins synthesized for the treatment of spent nuclear fuels and high level radioactive waste was evaluated. After irradiation at 10 MGy, only approximately 10% or less of the exchange groups were lost in HCl solutions regardless of their concentrations, while 3040% were lost in HNO₃. The pyridine resin has shown remarkable resistance against radiation particularly in HCl solution. It has been revealed that the decomposition of pyridine type resins results from the scission of the principal chains. An irradiation study was conducted also on the quaternary ammonium resins. Quatemization ratio was found to be reduced in HNO₃ solutions at 10 MGy irradiation.     

Polyurethane Dispersions Based on Sardine Fish Oil,Soybean Oil,and Their Interesterification Products

Alkyd resins were synthesized from different ratios of sardine fish oil and soybean oil. Three alkyd resin samples were styrenated. The styrenated alkyd resins and alkyd resins were subsequently converted into the polyurethane dispersions. The physicochemical properties, such as iodine value, saponification value, and specific gravity were determined. Infrared spectroscopy and nuclear magnetic resonance techniques were used for structural elucidation of newly synthesized resins. The coating properties, such as adhesion, flexibility, scratch hardness, pencil hardness, impact, solvent, and chemical resistance were evaluated. Thermogravimetric analysis was used to investigate the thermal stability of alkyd resin and polyurethane dispersions. Cost effective volatile organic components (VOC) compliant coatings for various applications can be synthesized successfully by partly replacing soybean oil with commercially available, inexpensive sardine fish oil.