Janus粒子的表面改性及其对共混聚合物的增容性能研究

本文以雪人状的SiO_2@PDVB Janus粒子为模板,通过表面改性获得具有不同表面性质的Janus粒子,包括在SiO_2半球分别引入聚丁二烯(PBd)与聚异戊二烯(PI),以增加SiO_2@PDVB Janus粒子中无机的SiO_2半球对聚合物基质的亲和性.随后将改性前后的Janus粒子分散到聚苯乙烯(PS)/顺丁橡胶(PBd)及聚苯乙烯(PS)/异戊橡胶(PI)的共混体系中,考察了不同Janus粒子对共混物相结构的影响.结果发现,与未改性的Janus粒子相比,引入聚合物刷的Janus粒子可更有效地提高其界面增容效果,抑制共混物相分离的动力学.     

SiO2粒子对PMMA/SAN共混体系相分离行为的影响

采用小角激光光散射(SALLS)并结合动态流变学方法,考察了气相法二氧化硅(SiO2)粒子的加入对聚甲基丙烯酸甲酯/苯乙烯-丙烯腈无规共聚物(PMMA/SAN)共混体系相行为的影响,得到了添加SiO2粒子前后的相图,发现SiO2粒子对基体相行为的影响与基体的组成有关.对PMMA/SAN(60/40)体系,加入SiO2粒子后相分离温度上升,但并未改变相分离机理,仍为亚稳单相分解过程(spinodal decomposition,SD);而对于PMMA/SAN(30/70)体系,加入SiO2粒子后却降低了体系的相分离温度.该现象可能是SiO2粒子和基体组分界面间组成与PMMA/SAN共混物基体组成的差异造成的.     

聚甲基丙烯酸甲酯/聚醋酸乙烯酯/纳米二氧化硅体系的相分离行为研究

研究了聚甲基丙烯酸甲酯/聚醋酸乙烯酯/纳米二氧化硅(PMMA/PVAc/silica)体系的相分离行为.通过傅里叶变换红外光谱和链缠结行为的研究发现PMMA和PVAc间存在较强的分子间相互作用,加入纳米二氧化硅导致2种聚合物在纳米粒子表面吸附,从而改变了分子间相互作用.体系中复杂的分子间相互作用以及纳米粒子-聚合物相互作用使得时温叠加严重失效,因此提出用归一化Cole-Cole图分析该体系的相分离过程.纳米粒子对不同组成体系相分离行为的影响不同,近临界组成中纳米粒子促进相分离并最终分布于两相界面,远临界组成中纳米粒子起成核作用并始终分布于海岛相中,这种由相分离机理决定的纳米粒子选择性分布为调控纳米粒子在聚合物中的组装结构提供了新的思路.     

核-壳粒子增韧聚合物的研究进展

核-壳粒子增韧结合了弹性体增韧和刚性粒子增强的优点，将其用于聚合物共混体系中有可能得到比基体树脂更高韧性更好刚性的复合材料。本文综述了相关核-壳粒子的分类、形态、形成机制，以及它们对聚合物基体的增韧机理，并详细阐述了反应性和非反应性聚合物共混体系中原位形成的核-壳粒子形态演化规律及其对共混物力学性能的影响。     

基板界面对PS/PMMA共混物薄膜相逆转组成比的影响

近年来高分子共混体系中的界面、表面效应逐渐引起了越来越多研究者的兴趣 .人们发现 ,当共混物薄膜厚度减至一定程度时 ,聚合物共混物薄膜中的相形态、相容性及相分离动力学与本体中有较大的不同[1～ 3] .基板界面作用对共混薄膜体系的热力学、动力学行为产生很大的影响 .我们以往的研究 [4 ,5]也发现 ,PP/EVAc(70 /30 )共混体系退火过程中 ,基板界面 (如玻璃 )作用可大大加速分散相(EVAc)粒子的粗化凝聚过程 .本研究用聚甲基丙烯酸甲酯和聚苯乙烯共混物的四氢呋喃溶液在不同基板介质 (如玻璃基板 ,PP基板 )上成膜 ,用相差显微镜观测了…     

碳系导电填料混杂填充聚合物共混体系的导电逾渗模型

以排除体积理论为基础,提出了3种碳系导电填料混杂填充聚合物共混体系的导电逾渗模型,并利用三维图和二维图对导电逾渗模型进行了描述.选用炭黑、聚团状碳纳米管和阵列碳纳米管3种导电填料,以聚碳酸酯(PC)/苯乙烯-丙烯腈共聚物(SAN)(70∶30,质量比)和PC/聚苯醚(PPO)(70∶30,质量比)2个共混体系进行研究,通过不同导电填料在单一聚合物及其共混物中逾渗值的测量,对导电逾渗模型公式的各个参数进行计算和修正.导电逾渗模型预测结果与样品实际电阻率基本吻合,证明了模型的普适性和实用价值.对于基体相不变的系列聚合物共混体系,可以通过任意一种导电填料在共混体系中的逾渗值及在基体相聚合物中的逾渗值之比得到模型公式的相关参数,从而极大地方便了模型的推广和应用.     

线性和非线性聚合物的相分离

分子共混物从20世纪60年代开始,引起很多科学家的兴趣.加工过程中,聚合物相分离过程中的热力学和动力学起了重要的作用,赋予了共混物一定的形貌,提供了很多人们需要的功能.关于聚合物的相分离问题,近年来无论在实验还是在理论上都得到了很大的发展.聚合物相分离的热力学是以Flory-Huggins的平均场理论为基础,动力学以CHC(Cahn-Hilliard-Cook)的线性理论为基础.在本文中,我们对亚稳相分离SD(Spinodal Decomposition)的热力学和动力学都进行了考察.描述了测量二元共混物的浓度涨落的静态散射实验,给出了在二元共混物体系的SD的近期理论计算.首先,从普适的Langevin方程推导CHC理论,从而给出CHC的唯象的平均场理论的微观图象.然后介绍模式耦合计算,从而将SD理论扩展到非线性区域.通过将短期SD分解与高分子共混物的对比揭示了定量计算的本质.最后,讨论了一些近年来在剪切场下相行为的研究以及该领域可能的发展方向.     

聚丙烯及其共混物/共聚物体系动态流变行为研究进展

聚丙烯共混物、共聚物具有复杂的凝聚态结构,其结构形态、相容性和相分离的研究一直是该领域的中心课题。与常规研究方法(DSC、DMA等)相比,动态流变学方法在研究聚合物结构与形态方面具有独特的优势,对聚合物形态结构的变化十分敏感。本文根据动态流变学基本理论,重点介绍和评述了动态流变学方法在研究聚丙烯及其共混物/共聚物体系形态结构、相容性以及相分离方面的最新进展。动态流变学方法被证明是研究聚丙烯基多相/多组分体系形态结构、相容性和相分离的有效手段。     

嵌段共聚物苯乙烯-丁二烯-苯乙烯(SBS)/苯酰化聚苯醚共混分相动力学

<正> 对高分子-高分子共混体系相分离动力学过程的研究,人们一般局限于均聚物-均聚物,均聚物-无规共聚物共混体系,对于均聚物-嵌段共聚物共混体系的分相过程很少涉及。原因其一是很难找到具有临界相行为的嵌段共聚物-均聚物共混体系,其二是嵌段共聚物存在微相分离,使得宏观相分离动力学过程研究变得复杂。Paul的工作似乎为这方面的研究工作开辟了道路。     

多相聚合物体系的归并行为研究进展

多相聚合物体系的相归并指热力学不相容的聚合物共混体系,发生相分离后,分散相粒子发生有效碰撞,分散颗粒聚集而长大的过程.本文综述了多相聚合物体系的相归并机理、研究方法及加工过程的归并行为.归并过程可以在退火条件下进行,也可以在剪切条件下进行.多相聚合物在熔融状态下的退火会引起分散相颗粒之间的聚集,称为静态归并.在一定的流...     

聚合物共混物的相容性及相分离

综述了聚合物共混物相容性和相分离的研究现状。介绍了聚合物共混物的相容性理论,影响相容性的因素及改善和相容性的方法和表征相容性的手段。聚合物共混物的相分离机理制约着材料的性能,旋节分离和成核－增长相分离分别形成不同的形态结构。旋节分离和成核－增长相分离所对应的动力学过程是不同的,散射光强与相分离时间分别满足指数和幂指数关系。     

高分子体系相分离动力学及图样生成和选择

高分子共混物的混合熵很小导致其多为热力学不相容体系而发生相分离,形成特定的时空图样。本文根据多年来我们自己的研究工作并结合实例,基于时间分辨的Ginzberg-Landau 方法研究高分子复杂体系相分离动力学及图样选择,重点介绍剪切外场下高分子共混物及嵌段高分子的相分离,耦合化学反应的相分离,在弯曲曲面特别是球面上的相分离,以及TDGL与密度泛函理论的有机结合即动态自洽场理论在具有不同链拓朴结构的嵌段高分子体系中研究相分离动力学。     

剪切流动对聚合物共混物相行为影响的研究进展

剪切流动对聚合物共混物相行为影响的研究进展;综述     

Interplay of chemical and physical factors in reacting polymer blends. Theoretical considerations

Various effects produced by copolymers in polymer blends are discussed, with an emphasis on the role of interchain interactions. Simple theoretical models are considered to study the following problems: the interplay of diffusion and macromolecular reaction in compatible and incompatible blends, the stabilizing effect of premade diblock copolymer on the system of minor phase particles in incompatible blends, the kinetics of transesterification in a homogeneous blend. The effect of diblock copolymer on the Ostwald ripening in a polymer blend is stated in more details; the possibility of narrowing the size distribution of minor phase particles is predicted.     

混合高聚物分相过程标度、分形与Monte Carlo模拟

基于光散射、Monte Carlo模拟标度理论和分形(Fractal)概念研究和分析了高分子混合体系不稳相分离过程结构函数的标度行为和成因, 结果表明相分离的形态是一种分形结构, 其分形维数不随时间变化. 结构函数的标度行为起源于相态的分形结构. 相态的分形结构是不稳相分离特征之一.     

Influence of Reactive Compatibilization on the Morphology of Polypropylene/Polystyrene Blends

To study the efficiency of different mechanisms for reactive compatibilization of polypropylene/polystyrene blends (PP/PS blends), main chain or terminal-functionalized PP and terminal-functionalized PS have been synthesized by different methods. While the in-situ block and graft copolymer formation results in finer phase morphologies compared to the corresponding non-reactive blends, the morphology development in the ternary blend system PP/PS + HBP (hyperbranched polymer) is a very complex process. HBP with carboxylic acid end groups reacts preferably with the reactive sites of the oxazoline functionalized PS (PS-Ox) and locates mainly within the dispersed PS-Ox phase. A bimodal size distribution of the PS-Ox particles within the oxazoline modified PP (PP-Ox) matrix phase is observed with big PS-Ox particles (containing the HBP as dispersed phase) and small PS-Ox particles similar in size to the unimodal distributed particles in the non-reactive PP-Ox/PS-Ox blends. Factors influencing the morphology are discussed.     

Miscibility and phase separation in polymer blends studied by laser light scattering

In this paper major emphasis has been placed on the phase behavior of miscible polymer blends, especially on blends containing random copolymers. Blends containing random copolymers generally tend to phase separation at elevated temperatures (LCST behavior). Experimental determination of miscibility areas as a function of temperature and copolymer composition by laser light scattering provides the interaction parameters necessary for theoretical explanations and predictions of various phase separation phenomena. Just above the LCST polymer blends exhibit regular highly interconnected two-phase morphologies. The rate of decay of these structures is estimated. The phase separation kinetics can be pursued by laser light scattering and is discussed in terms of CAHN's linearized theory. It can be shown that the linear theory adequately describes the early stage of phase decomposition. The linear theory is also applicable to the reverse phenomenon, the phase dissolution below LCST. unlike the case of phase separation the diffusion-controlled regime is that in the late stage of phase dissolution.     

Phase behavior of polymer/diluent/diluent mixtures and their application to control microporous membrane structure

Rechargeable battery separators containing controlled pores were fabricated via the thermally-induced phase separation (TIPS) process. Based on the idea that pores could be manipulated by controlling the liquid–liquid phase separation temperature in the TIPS process, phase boundaries of the polymer–diluent systems were controlled by using diluent mixtures. Phase behaviors of the polymer/diluent/diluent ternary blends consisting of polyethylene (PE) as polymer, and soybean oil (SBO) and dioctyl phthalate (DOP) as diluents were explored. PE/SBO and PE/DOP binary blends, and PE/SOB/DOP ternary blends exhibited typical upper critical solution temperature (UCST) type phase behaviors, and the phase separation temperatures of the PE/SBO blends were higher than those of the PE/DOP blends. When the mixing ratio of the polymer and diluent-mixture was fixed, the phase separation temperature of the PE/SBO/DOP blend initially increased with increasing SBO content in the diluent-mixture passing through a maximum centered at about 80 wt% SBO and decreased beyond this point. Furthermore, the phase separation temperature of the PE/diluent-mixture blend was always higher than that of the PE/SBO blend when the diluent-mixture contained more than or equal to 50 wt% SBO. To understand the observed phase behavior of the blends, thermodynamic analyses based on the lattice-fluid theory were performed. Larger pore membranes were fabricated from the blend when higher phase separation temperatures of the blend were exhibited.     

Reactive processing of syndiotactic polystyrene with an epoxy/amine solvent system

Syndiotactic polystyrene (sPS) is a new semi-crystalline thermoplastic which is believed to fill the price-performance gap between engineering and commodity plastics. In order to reduce the high processing temperature of sPS (>290°C), an epoxy-amine model system was used as a reactive solvent. Such a processing aid can be used to achieve a 50 to 500 fold lowering of the melt viscosity. When initially homogeneous solutions of sPS in a stoechiometric epoxy-amine mixture are thermally cured, Reaction Induced Phase Separation (RIPS) takes place, leading to phase separated thermoplastic-thermoset polymer blends. We focus our study on low (wt% sPS < 20%) and high concentration blends (wt% sPS > 60%) prepared by two processing techniques (mechanical stirring in a laboratory reactor or internal mixer/ reactive extrusion respectively). These blends have different potential interests. Low concentration blends (sPS domains in an epoxy-amine matrix) are prepared to create new, tunable blend morphologies by choosing the nature of the phase separation process, i.e. either crystallisation followed by polymerization or polymerization followed crystallisation. High concentration blends (sPS matrix containing dispersed epoxy-amine particles after RIPS) are prepared to facilitate the extrusion of sPS. In this case, the epoxy amine model system served as a reactive solvent. The time to the onset of RIPS is in the order of 7-9 min for low concentration blends, while it increases to 20-45 min for high concentration samples, as the reaction rates are substantially slowed down due to lower epoxy and amine concentrations. During the curing reaction the melting temperature of sPS in the reactive solvent mixture evolves back from a depressed value to the level of pure sPS. This indicates a change in the composition of the sPS phase, caused by (complete) phase separation upon reaction. We conclude that our epoxy amine system is suited for reactive processing of sPS, where final properties depend strongly on composition and processing conditions.