催化剂分子结构及共聚物配体的交替结构与其催化活性关系的理论研究

采用以ＡＳＥＤ－ＭＯ为基础的结构自动优化的ＥＨＴＯＰＴ法及Ｍｏｎｔｅ－Ｃａｒｌｏ法，对甲醇羰基化制乙酸的催化剂分子结构及共聚物配体的交替结构进行了理论研究。     

共聚物铑配合物催化甲醇羰基化速控步骤的理论研究

采用以原子重叠及电子离域的分子轨道理论ＡＳＥＤ ＭＯ（含原子对排斥的ＥＨＭＯ法）为基础的结构自动优化法，对共聚物铑配合物催化甲醇羰基化制乙酸反应速率控制步骤 氧化加成进行了理论研究．计算了不同共聚物配体形成的铑催化剂与碘甲烷的氧化加成反应途径，并得到反应活化能，分析了氧化加成反应过程中的电子转移和空间因素对活化能的影响，计算结果与实验结果是相符的，并从理论上解释了２ 乙烯基吡啶形成的共聚物铑配合物催化活性高于４ 乙烯基吡啶形成的共聚物铑配合物催化活性的原因．     

聚醚醚酮链段连接方式与其性能关系的研究

利用亲核取代反应,通过缩聚法合成了一种新型聚芳醚酮50％交替共聚物PEDEK-PETMDEK,通过¹HNMR证明其具有预期的结构.通过考察50％无规共聚物、50％交替共聚物、均聚物PEDEK和PET-MDEK的溶解性和热性能,发现聚醚醚酮共聚物的链段连接方式对聚合物性能有很大影响.50％交替共聚物是一种无定形固体,易溶于通常的有机溶剂,而50％无规共聚物却是半结晶聚合物,除浓硫酸外几乎不溶于任何溶剂;50％交替共聚物具有比50％无规共聚物更高的玻璃化转变温度.     

完全交替结构乙烯-丙烯共聚物的制备与表征

对顺-1,4含量为100%的高顺式聚异戊二烯(HCPI)进行加氢反应,得到了序列结构高度规整的乙烯-丙烯交替共聚物(alt-EP).所用的HCPI有适当的分子量(Mn=41×104)和极窄的分子量分布(Mw/Mn=1.02).HCPI的加氢反应以环烷酸镍和三异丁基铝为催化剂,在60℃和4.0MPa氢压的条件下反应3h,加氢产物的加氢度为100%.GPC测试结果显示所得乙烯-丙烯交替共聚物保持了窄分布的特点,表明HCPI加氢后未发生交联和降解反应;NMR,FTIR和广角X射线衍射测试结果表明此乙烯-丙烯交替共聚物具有高度规整的序列结构,为完全交替结构的乙烯-丙烯共聚物.并通过TGA和DSC对乙烯-丙烯交替共聚物的热性能进行了表征.     

两种[对苯乙炔-2,5-二(十二烷氧基)对苯乙炔]共聚物的合成及性能研究

用含氯前聚物路线和Ｈｅｃｋ反应分别合成［对苯乙炔－２，５－二（十二烷氧基）对苯乙炔］无规共聚物及交替共聚物．由元素分析、凝胶渗透色谱、吸收光谱及ＤＳＣ对其进行表征，研究了共聚物的组成与导电率、溶解性及发光性能的关系．比较了无规共聚物与交替共聚物在性能上的差别．     

阳离子钯—手性二膦配体催化剂存在下1—辛烯与一氧化碳对映选择性交替共聚

用阳离子钯-手性配体DDPPI（1,4-3,6-dianhydro-2,5-dideoxy-2,5-dis(diphenylphosphino)-L-iditol)催化剂,实现了一氧化碳与1-辛烯的对映选择性交替共聚。实验证明,手性配体对共聚具有非常好的手性诱导效应。旋光度、元素分析、碳谱、氢谱、红外光谱分析证明,所合成的1-辛烯-一氧化碳共聚物具有旋光活性及全同、交替共聚（1,4-酮）结构。     

乙烯基单体-N-苯基马来酰亚胺共聚物序列结构研究

用NMR谱研究了甲基丙烯酸甲酯(MMA)-N-苯基马来酰亚胺(PMI)、苯乙烯(St)-PMI共聚物的序列结构.结果表明,MMA-PMI共聚物单元属无规序列分布,St-PMI共聚物单元属交替序列分布.由¹HNMR结果可得MMA-PMI共聚物空间立构部分信息,由¹³CNMR三单元组实验结果算得的序列长度与末端基理论计算结果一致,且MMA-PMI共聚物链属一级Markov链.由St-PMI共聚物序列长度与末端基理论计算结果的偏差提出更为合理的增长基元反应.     

马来酸与二甲基烯两基胺共聚合成结构规整的聚两性电解质的研究

研究了马来酸与二甲基烯丙基胺共聚物的组成及其交替共聚机理。对共聚物等电点、絮凝性能测定结果表明，该共聚物具聚两性电解质的特性。通过红外光谱及差热分析，探讨了共聚物的微观结构。     

共聚物铑配合物催化甲醇羰基化制备醋酸的反应动力学分析

以共聚物铑配合物催化甲醇羰基化经醋酸甲酯到醋酸的反应，具有高稳定性、高活性的特点．本文通过对作者近期研究工作的总结，绘出此催化反应全过程的循环图，并在此基础上求出有关动力学参数，结果计算值与实验值相符，证明此机理的合理性，并讨论了几种共聚物配体之间的差异．     

硫醇类配体修饰金纳米粒子在嵌段共聚物中自组装的研究进展

本文综述了不同类型硫醇配体修饰金纳米粒子的合成方法以及功能性金纳米粒子在嵌段共聚物薄膜中的自组装研究进展,重点介绍了硫醇类配体修饰金纳米粒子的合成方法,包括Brust合成法、原位合成法、grafting from合成法、配体置换法、单晶模板法等。总结了硫醇基小分子或聚合物配体修饰的金纳米粒子与嵌段共聚物之间自组装的调控方法,如利用配体与嵌段共聚物组分的隔离作用、配体与嵌段共聚物组分形成的氢键作用、溶剂蒸气退火或热退火等诱导嵌段共聚物/纳米粒子复合薄膜自组装。展望了功能性金纳米粒子以及嵌段共聚物/金纳米复合材料的发展方向。     

Monte Carlo simulation on symmetric ABA/AB copolymer blends in confined thin films

The effects of blend composition on morphology, order-disorder transition (ODT), and chain conformation of symmetric ABA/AB copolymer blends confined between two neutral hard walls have been investigated by lattice Monte Carlo simulation. Only lamellar structure is observed in all the simulation morphologies under thermodynamic equilibrium state, which is supported by theoretical prediction. When the composition of AB diblock copolymer (phi) increases, both lamellar spacing and the corresponding ODT temperature increase, which can be attributed to the variation of conformation distribution of the diblock and the triblock copolymer chains. In addition, both diblock and triblock copolymer, chains with bridge conformation extend dramatically in the direction parallel to the surface when the system is in ordered state. Finally, the copolymer chain conformation depends strongly on both the blend composition and the incompatibility parameter chiN.     

低相对分子质量苯乙烯-马来酸酐交替共聚物的合成

将引发剂偶氮二异丁腈(AIBN)、共聚单体苯乙烯(St)和马来酸酐(MA)溶解于甲苯中,采用沉淀聚合法合成苯乙烯-马来酸酐共聚物(SMA).分别研究了反应温度、引发剂用量、反应时间、单体配比和单体浓度对聚合物得率和酸酐含量的影响.采用正交实验确定最优反应条件为:单体浓度20%,单体物质的量比为1∶1,引发剂用量为0.60%,反应温度为86℃,反应时间2h,产物得率为86.86%,酸酐含量为50.28%.并利用傅里叶变换红外光谱(FTIR)、核磁共振碳谱(~(13)C NMR)、凝胶渗透色谱(GPC)和热分析法分别研究聚合物的分子结构、相对分子质量及相对分子质量分布和热稳定性.结果表明产物是苯乙烯-马来酸酐交替共聚物,相对分子质量分布较窄,具有良好的热稳定性.     

Study of pH-sensitive copolymer/phospholipid complexes using the langmuir balance technique: effect of anchoring sequence and copolymer molecular weight

The behavior of three copolymers of N-isopropylacrylamide (NIPAM), methacrylic acid (MAA), and hydrophobic moiety was studied at phospholipid monolayer/subphase interfaces. The hydrophobic moieties, N-terminal dioctadecylamine (DODA) and random octadecylacrylate (ODA), were used as anchoring groups. The interactions between a 1,2-distearoyl-sn-glycero-3-phosphatidylcholine (DSPC) monolayer and the copolymers were studied using the Langmuir balance technique. The effect of subphase pH, distribution of anchors along the copolymer chain, and copolymer molecular weight on the nature of the interactions between the copolymer chains and the DSPC monolayer were investigated. A first-order kinetics model was used to analyze the copolymers adsorption at the DSPC monolayer/subphase interface and allowed the interaction area between the copolymer chains and the DSPC monolayer, A(x), to be determined. The interaction area appears to depend on the subphase pH and the copolymer molecular weight. On decreasing pH, the interaction area of high molecular weight copolymers increases significantly; this is consistent with the copolymer chain phase transition from an extended coil to a collapsed globule while pH is lowered. In the latter conformation, strong hydrophobic attractive interactions between the copolymer chains and the hydrophobic part of the DSPC monolayer favor the copolymer intercalation, which could eventually provoke the phospholipidic layer destabilization or rupture.     

Multicompartment micelles from star and linear triblock copolymer blends

Dissipative particle dynamics simulations were performed on multicompartment micelles formed by blending star and linear triblock copolymers, in which the influences of blending options and blending ratio as well as copolymer chain compositions were studied systematically. The results show that blending of copolymers with different architectures is a promising strategy to control the morphology and structure of multicompartment micelles. This work revealed several new morphologies of multicompartment micelles by blending star and linear triblock copolymers, and the dynamic processes were elucidated at the molecular level by tracing the motions of copolymer chains. The results of this work provide deep insight into micro/mesoscopic details of the underlying mechanisms, contributing to a more complete understanding of multicompartment micelle formation and structural control.     

Facile preparation and characterization of copolymer nanoparticles from pyrrole and aniline-2-sulfonic acid

Novel poly(pyrrole-co-aniline-2-sulfonic acid) (PPYAS) nanoparticles were prepared via chemical oxidative polymerization of pyrrole and aniline-2-sulfonic acid in different aqueous solutions without any external additives. The morphology, structure and electroconductivity of the HCl-doped particles were studied by changing the molar ratio of the oxidant and monomers, and the solvent for polymerization. It was found that the yield, mean diameter and electrical conductivity of the resulting particles varied strongly with the molar ratio of the components. The nanoparticles exhibit a minimum mean diameter of around 62 nm, and good self-stability because of the introduction of sulfo groups into the chains of the copolymer. The preparation affords yield of up to 85%, and the HCl-doped copolymer salts possess an electroconductivity between 0.68 and 0.2 S/cm, depending on the fraction of anilinesulfonic acid.     

Studies on microstructure and aqueous solution properties of block copolymer of acrylamide-styrene

Three series of block copolymers of acrylamide (AM) and styrene (St) as hydrophobic comonomer with varied microstructures were prepared in microemulsion medium by changing feed ratio of monomers, ratio of St to surfactant, and amount of initiator, respectively. The effects of microstructure factors of the amphiphilic block copolymers PAM-b-PSt on their aqueous solution properties were investigated by fluorescence probe technique and surface tension measurement in detail. The experimental results show that the aqueous solution properties of PAM-b-PSt are strongly dependent on their microstructure factors, such as the length and content of PSt hydrophobic blocks in the copolymers and their molecular weight. It was found that the main microstructure factors which effect the hydrophobic association behavior of the copolymer PAM-b-PSt are the length and content of PSt hydrophobic blocks in the copolymer, whereas the hydrophobic association behavior of the copolymer is not affected nearly so much by molecular weight in more dilute regions. At the same time, it was also found that the main microstructure factors which affect the surface activity of the copolymer are the content of PSt hydrophobic blocks in the copolymer and molecular weight, whereas the length of PSt blocks in copolymer does not affect surface activity of the copolymer nearly so much under fixed content of PSt hydrophobic blocks and molecular weight in the copolymer.     

Conformation studies on sol-gel transition in triblock copolymer solutions

The gelation of physically associating triblock copolymers in a good solvent was investigated by means of the Monte Carlo simulation and a gelation process based on the conformation transition of the copolymer that was described in detail. In our simulative system, it has been found that the gelation is closely related with chain conformations, and there exist four types of chains defined as free, dangling, loop, and bridge conformations. The copolymer chains with different conformations contribute to the formation of gel in different ways. We proposed a conformational transition model, by which we evaluated the role of these four types of chains in sol-gel transition. It was concluded that the free chains keeping the conformation transition equilibrium and the dangling conformation being the hinge of conformation transition, while the chain with loop conformation enlarges the size of the congeries and the chain with bridge conformations binds the congeries consisted of the copolymer chains. In addition, the effects of temperature and concentration on the physical gelation, the association of the copolymer congeries, and the copolymer chain conformations' distribution were discussed. Furthermore, we employed the structure factor analysis to study the association of copolymer conformations and long-range order of the simulation system and found our results are in agreement with the previous experimental conclusions.     

Synthesis of graft copolymer of ethyl cellulose through living polymerization and its self-assembly

Copolymers of ethyl cellulose (EC) with polystyrene (PSt) were synthesized through atom transfer radical polymerization (ATRP). The molecular weight of graft copolymers increased without any trace of the EC macro-initiator, and the polydispersity of the side chains was low. The molecular weight of the side chains increased with the monomer conversion. Kinetic study indicated that the polymerization was first order. The micelle characteristics of the graft copolymer in acetone were investigated using dynamic light scattering (DLS), atom force microscopy (AFM) and transmission electron microscopy (TEM). With increasing the concentration, micelles were gradually formed from the solution. The TEM and AFM images indicated that the micelles had spherical shape and showed core-shell structure.     

Characterization of styrene–acrylonitrile copolymer by pyrolysis gas chromatography

Samples of styrene–acrylonitrile (SAN) copolymer of different compositions, molecular weights, block copolymers, and a blend of styrene and acrylonitrile homopolymers were prepared and characterized by the method of pyrolysis gas chromatography. On decomposition of SAN copolymer samples at 645°C, eleven components were identified, the most important of them being styrene, acrylonitrile, and propionitrile. By examination of the pyrolyzate composition during pyrolysis of the SAN copolymer of different compositions, it was established that the propionitrile yield was definitely decreased when the acrylonitrile concentration in copolymer was about 60 mole-%. Further, from the propionitrile yield, we could distinguish random SAN copolymer from the styrene-acrylonitrile homopolymer blend, and on the basis of propionitrile yield some information on the molecular structure of the copolymer could be obtained. The styrene yield depends linearly on the copolymer composition. This permits determination of copolymer composition on the basis of the styrene yield. Furthermore, the effects of decomposition temperature and of molecular weight on the yields of styrene and acrylonitrile were examined.