新型X光显影含糖聚合物的合成与表征

用自由基本体聚合方法合成了一种新型的X光显影含糖三元共聚物P(2-IEMA-AcGEMA-MMA). 探讨了单体配比和链转移剂用量对聚合物分子量及其分布的影响, 并用FTIR, 1H NMR和GPC对其结构进行了表征. 研究结果表明, 改变单体配比对聚合物的分子量几乎不产生影响, 但减少链转移剂用量时, 可明显增加三元共聚物的分子量. 聚合物分子量分布一般在2~3之间, 符合自由基聚合产物分子量分布的一般规律. 聚合物具有良好的显影性, 显影效果随着样品厚度的增加而增强.     

异丙醇铝改进的原子转移自由基聚合催化体系

以α 溴代异丁酸乙酯［２ （ＥｉＢ） Ｂｒ］ 为引发剂,溴化亚铜（ＣｕＢｒ）／ 联二吡啶（ｂｐｙ）／ 异丙醇铝［Ａｌ（ＯｉＰｒ）３］ 为复合催化剂,在环己酮溶液中进行了甲基丙烯酸正丁酯（ＢＭＡ） 的原子转移自由基聚合（ＡＴＲＰ） ．研究了异丙醇铝对聚合速率及产物分子量分布的影响．异丙醇铝可与引发剂和聚合物中的羰基配位,使相邻的Ｃ—Ｂｒ 键活化,ＡＴＲＰ 反应可以在较低温度下进行．适量溴化铜的加入,可调节ＡＴＲＰ 活性,可得到分子量可控且分子量分布窄的ＰＢＭＡ（ ＭＷＤ＝ １－３ ～１－５） ．     

微波辐射下甲基丙烯酸正丁酯原子转移自由基聚合

原子转移自由基聚合(Atom transfer radical polymerization,ATRP)与其他活性聚合方法相比,具有适用单体广、反应条件温和。但其催化体系活性不高,聚合温度较高,数均分子量不高。     

光聚合法快速制备甲基丙烯酸酯类毛细管整体柱

采用甲基丙烯酸正丁酯(BMA)为功能单体, 乙二醇二甲基丙烯酸酯(EDMA)为交联剂, 正丙醇、1,4-丁二醇和水为致孔剂, Irgacure 1800为引发剂, 在毛细管内采用光引发原位聚合150 s快速制备了有机聚合物整体柱. 分别采用电色谱(CEC)、加压电色谱(p-CEC)和低压色谱(LPLC)模式对所制备的整体柱进行了性能评价, 基线分离了硫脲、甲苯、萘和联苯, 在加压电色谱(p-CEC)模式下硫脲的最低理论塔板高度达到了8.0 μm. 扫描电镜结果表明, 整体材料在毛细管柱中形成并与毛细管内壁结合紧密.     

自由基照相的光显影研究

非银盐感光材料与卤化银感光材料相比具有很高的分辨力,但灵敏度较低,限制了它的应用范围。因此,如何提高非银盐感光材料的灵敏度一直是非常活跃的研究领域。     

聚酰亚胺类液晶光定向层材料的研究

经含有羟基的二胺单体HAB与二酐单体 4 ,4′ (六氟异丙基 ) 双邻苯二甲酸酐 ( 6FDA)的缩聚反应 ,制备了含有羟基的先驱聚合物PI OH ,通过PI OH上羟基与肉桂酰氯的酯化反应 ,制备了侧链带有肉桂酸酯基团的光敏聚酰亚胺PI CI.用氢核磁共振 ( 1H NMR)分析、傅立叶红外光谱 (FTIR)分析等表征了上述聚合物的结构与感光性能 .用紫外 可见光谱 (UV Vis)等方法研究了PI CI的光交联反应 .聚合物PI CI旋镀膜经线性偏振光聚合技术 (LPP)处理并装配得到的液晶盒可使液晶分子很好地定向沿面排列 .上述实验表明 ,本文所合成的聚酰亚胺定向层材料是一种新的液晶光定向层材料     

原子转移自由基聚合合成(甲基)丙烯酸酯类模型聚合物及其动力学研究

本文采用一种新颖的活性自由基聚合—原子转移自由基聚合（ＡＴＲＰ）的方法，以１－溴代苯乙烷作为引发剂，过渡金属卤化物与配位剂络合物（ＣｕＢｒ／２，２’－联吡啶）为催化体系，环己酮为溶剂，进行了甲基丙烯酸正丁酯（ＢＭＡ）和丙烯酸正丁酯（ＢＡ）的活性聚合。得到具有指定分子量和窄分子量分布（１．２＜Ｍｗ／Ｍｎ＜１．５）的模型聚合物。计算并讨论了两聚合体系的ＡＴＲＰ的动力学数据     

可见光响应的荧光增白剂基多功能光引发体系

将4,4’-双(苯并噁唑-2-基)二苯乙烯(BBS)、7-二乙氨基-4-甲基香豆素(C 1)、双-(三嗪基氨基)-二苯乙烯二磺酸(CBUS 450)、4,4’-双(2-磺酸苯乙烯基钠)联苯(CBS X)和1,4-双(2-苯并噁唑基)萘(OB 7)等5种含有不同荧光发射基团的商用荧光增白剂分别与二苯基碘鎓六氟磷酸盐(IOD)组成二元光引发体系,再与N-乙烯基咔唑(或叔胺)组成三元光引发体系,在可见光发光二极管(LED)光源辐照下,通过自由基聚合反应制备丙烯酸酯树脂,同时通过阳离子/自由基同步聚合反应制备互穿网络聚合物.利用紫外-可见分光计荧光分光计、电子自旋共振波谱仪、傅里叶变换红外光谱仪、扫描电子显微镜和原子力显微镜对荧光增白剂和互穿网络聚合物进行了表征.研究结果表明,荧光增白剂在可见光LED的照射下可作为具有高效能的多功能光引发剂.其中苯并噁唑-萘衍生物(OB 7)、三嗪茋衍生物(CBUS 450)、二苯乙烯-联苯衍生物(CBS X)和香豆素衍生物(C 1)基二元光引发体系和三元光引发体系即使在空气中也表现出了优异的光引发能力.     

采用阴离子、基团转移及自由基聚合方法合成旋光性聚甲基丙烯酸薄荷酯

近年来, 旋光性高分子的广泛应用及其特有的功能已引起了广泛关注, 尤其在手性记忆功能材料[1～3]、液晶及手性催化等方面[4～6]皆表现出良好的应用前景. 用旋光性单体合成旋光性聚合物是最常用的方法之一. 早在20世纪70年代, 就有关于聚甲基丙烯酸薄荷酯(PMnMA)的研究[7], 但有关配体参与的阴离子聚合, 基团转移聚合(GTP)及其立构规整性的研究还未见报道.     

Polymer Photovoltaic Cells Based on Polymethacrylate Bearing Semiconducting Side Chains

Polymethacrylate with semiconducting side chains ( P1 ), synthesized by free radical polymerization, was used as a donor material for polymer solar cells. P1 is of high molecular weight (M _n = 82 kg mol⁻¹), good thermal stability, narrow band gap (1.87 eV), and low‐lying HOMO energy level (−5.24 eV). P1 possesses not only the good film‐forming ability of polymers but also the high purity of small organic molecules. Power conversion efficiencies (PCEs) of 0.63% and 1.22% have been obtained for solar cells with M1 :PC₇₁BM and P1 :PC₇₁BM as the active layers, respectively. With PC₆₁BM as the acceptor, PCEs of M1 and P1 based devices decrease to 0.61% and 0.76%, respectively. To the best of our knowledge, this is the first report that free radical polymerization can be used to prepare polymer donors for photovoltaic applications.     

α，ω-二羧基-甲基丙烯酸丁酯低聚物的合成及MS分析

利用传统自由基聚合法，在四氢呋喃溶液中自由基引发聚合甲基丙烯酸丁酯单体而得到ω-羧基-甲基丙烯酸丁酯低聚物(CTBMA)(分子量在1500左右)；利用CTBMA末端酯基的反应特性，在二氧六环／水／KOH混合溶液中皂化CTBMA，使之转化为α，ω-羧基甲基丙烯酸丁酯低聚物(di-CTBMA)；研究了溶剂的类别、反应时间等反应条件对皂化产物结构的影响；利用MALDI-TOF-MS及LSIMS对皂化各阶段产物进行了分析监测．实验表明，在适当的皂化条件下，CTBMA皂化时主要为末端酯基转化为羧基，相应得到的产物di-CTMBA具有很好的结构特性，其官能团度(functionality)接近2．     

Kinetics of Bulk Free‐Radical Polymerization of Butyl Methacrylate Isomers Studied by Reaction Calorimetry

The kinetics of bulk free‐radical polymerizations of n‐butyl methacrylate (n‐BMA), iso‐butyl methacrylate (i‐BMA), and tert‐butyl methacrylate (t‐BMA) are studied by differential scanning calorimetry and with the aid of a mathematical model previously reported by the authors. In all the cases, the rate of polymerization (R_p) evolution curve exhibits a minimum at low conversions and the characteristic maximum of the autoacceleration effect. It is found that the monomer conversion x_min at which the minimum is observed, follows the order n‐BMA > i‐BMA > t‐BMA and that for monomer conversions (x) smaller than x_min, the termination rate coefficient (k_t) shows a plateau. According to the model results it is obtained that for x > x_min, the termination reaction is chemically controlled whereas for x > x_min, it is diffusion‐controlled and that the x_min values are related to the value of the termination rate coefficient of the chemical step (k_t0) of every isomer, which is highly influenced by the steric hindrance of the alkyl substituent group.     

Atom transfer radical polymerization of n‐butyl methacrylate in an aqueous dispersed system: A miniemulsion approach

Ultrasonication was applied in combination with a hydrophobe for the copper‐mediated atom transfer radical polymerization of n‐butyl methacrylate in an aqueous dispersed system. A controlled polymerization was successfully achieved, as demonstrated by a linear correlation between the molecular weights and the monomer conversion. The polydispersities of the polymers were small (weight‐average molecular weight/number‐average molecular weight < 1.5). The influence of several factors, including ultrasonication, the amount of the surfactant, and the nature of the initiator, on the polymerization kinetics, molecular weight, and particle size was studied. The polymerization rate and molecular weights were independent of the number of particles and only depended on the atom transfer equilibrium. The final particle size, however, was a function of all the parameters. © 2000 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 38: 4724–4734, 2000     

Synthesis of 4-arm methyl methacrylate star polymer by atom transfer radical polymerization

The synthesis of 4-arm methyl methacrylate star polymer had been achieved successfully by atom transfer radical polymerization using CuCl as catalyst, 2, 2′-bipyridyl as ligand and pentaerythritol tetrakis (2-bromoisobutyrate) as the initiator. The star polymer was characterized by ¹H-NMR and GPC, by which the precise 4-arm structure of the PMMA was confirmed. __________ Translated from Journal of Shaanxi Normal University (Natural Science Edition), 2008, 36(2) (in Chinese)     

Effect of reaction conditions on the grafting of 2-(dimethylamino)ethyl methacrylate onto hydrocarbon substrates

The grafting of 2-(dimethylamino)ethyl methacrylate (DMAEMA) onto two model hydrocarbons, squalane and n-eicosane, and to linear low density polyethylene (LLDPE) has been investigated. The results of the study indicate that a high reaction temperature, 160°C, and a low concentration of monomer, less than 0.3 M, are optimum conditions for the grafting reaction. Reaction products, which consisted of grafted hydrocarbons and poly(DMAEMA), were separated by solvent extraction and vacuum distillation; samples were then analyzed by NMR and FTIR spectroscopy and size exclusion chromatography. ¹H-NMR spectroscopy indicates that grafted squalane contained approximately 6 DMAEMA units per squalane residue. ¹H- and ¹³C-NMR and molecular weight studies strongly suggest that the grafts onto the model hydrocarbons consist of single DMAEMA units. Results of the melt grafting of DMAEMA onto LLDPE show that the grafting efficiency and degree of grafting are substantially lower than were expected from the model system. © 1994 John Wiley & Sons, Inc.     

Synthesis of well‐defined cyclodextrin‐core star polymers

The synthesis of 21‐arm methyl methacrylate (MMA) and styrene star polymers is reported. The copper (I)‐mediated living radical polymerization of MMA was carried out with a cyclodextrin‐core‐based initiator with 21 independent discrete initiation sites: heptakis[2,3,6‐tri‐O‐(2‐bromo‐2‐methylpropionyl]‐β‐cyclodextrin. Living polymerization occurred, providing well‐defined 21‐arm star polymers with predicted molecular weights calculated from the initiator concentration and the consumed monomer as well as low polydispersities [e.g., poly(methyl methacrylate) (PMMA), number‐average molecular weight (M_n) = 55,700, polydispersity index (PDI) = 1.07; M_n = 118,000, PDI = 1.06; polystyrene, M_n = 37,100, PDI = 1.15]. Functional methacrylate monomers containing poly(ethylene glycol), a glucose residue, and a tert‐amine group in the side chain were also polymerized in a similar fashion, leading to hydrophilic star polymers, again with good control over the molecular weight and polydispersity (M_n = 15,000, PDI = 1.03; M_n = 36,500, PDI = 1.14; and M_n = 139,000, PDI = 1.09, respectively). When styrene was used as the monomer, it was difficult to obtain well‐defined polystyrene stars at high molecular weights. This was due to the increased occurrence of side reactions such as star–star coupling and thermal (spontaneous) polymerization; however, low‐polydispersity polymers were achieved at relatively low conversions. Furthermore, a star block copolymer consisting of PMMA and poly(butyl methacrylate) was successfully synthesized with a star PMMA as a macroinitiator (M_n = 104,000, PDI = 1.05). © 2001 John Wiley & Sons, Inc. J Polym Sci Part A: Polym Chem 39: 2206–2214, 2001     

Activity of the furfuryl ring in the free radical polymerization of acrylic monomers

The effect and the participation of the furfuryl ring, in particular the hydrogen at position C-5 in the free radical polymerization are analyzed following the polymerization of furfuryl acrylate (FA) and furfuryl methacrylate (FM) initiated by AIBN under photochemical activation. The results obtained indicate that the polymerization of FA deviates from the classical free radical kinetic scheme, giving rise to crosslinked polymers even at a degree of conversion lower than 7%. This behavior is well explained taking into consideration the participation of the furfuryl ring which acts as a degradative transfer agent. This was demonstrated by the kinetic analysis of the free radical polymerization of MMA initiated by the thermal decomposition of AIBN in the presence of different concentrations of furfuryl acetate. © 1996 John Wiley & Sons, Inc.