用甲基铝氧烷活化的氯化稀土催化剂合成高顺式窄分布聚丁二烯

以NdCl3.4L(配体L为膦酸三丁酯TBP、膦酸三苯酯TPP、膦酸二异辛酯P204)为主催化剂(简称[Nd])、甲基铝氧烷(MAO,简称[Al])为助催化剂和环己烷为溶剂,进行1,3-丁二烯聚合的研究.考察了配体对丁二烯聚合反应活性的规律及MAO用量、催化剂陈化时间、溶剂种类对聚合的影响;并对聚合物进行NMR,IR和GPC的表征.结果表明,3种配体的聚合活性顺序为TBP>P204>TPP;当[Al]/[Nd]为30时,聚合物的分子量分布指数达到1.20;30℃陈化时,聚丁二烯cis-1,4结构均大于97%;与正己烷、甲苯溶剂对比来看,环己烷体系所得聚合产物的分子量分布相对较窄、产率较高.     

ATRP法合成结构对称的双羧基聚苯乙烯及其超分子的形成

从二甲苯出发,经过溴甲基化反应、氧化反应、酯化反应和溴代反应,合成了一种四官能团的引发剂,4,6-二(溴甲基)-1,3-苯二甲酸二甲酯.用该引发剂引发苯乙烯进行原子转移自由基聚合,实验结果表明聚合反应具有活性自由基聚合的特征.通过苯乙烯的本体聚合反应获得了分子量可控、双酯基位于聚合物链中间的聚苯乙烯.经过水解反应,使聚合物中的双酯基被水解成双羧基,从而得到了结构对称的两亲性聚合物,双羧基聚苯乙烯.利用该聚合物具有分子识别的特性,与十二烷胺形成了离子键超分子化合物.此工作为超分子星形聚合物的设计合成提供了简便快捷的方法.     

(-)-双(薄荷基甲酰基)苯基氧化膦的合成及在自由基光聚合中的螺旋选择性

以苯基二氯化膦和薄荷基甲酸为原料, 合成了一种手性双酰基膦氧化物光引发剂(-)-双(薄荷基甲酰基)苯基氧化膦. 采用核磁共振谱、 质谱及元素分析确定了该化合物的结构, 并测定了其螺旋诱导能力. 结果表明, (-)-BMPPO在引发自由基光聚合大位阻的单体甲基丙烯酸-1-苯基二苯并环庚酯(PDBSMA)的反应中具有螺旋选择性. 所得聚合物具有高度全同结构并显示出光学活性, 说明该聚合物形成了稳定的单手性螺旋链构象. 降低单体与引发剂的投料比及提高聚合温度有利于增加反应的螺旋选择性. 在手性薄荷醇溶剂中, 由(2,4,6-三甲基苯甲酰基)二苯基氧化膦(TPO)引发单体PDBSMA的光聚合反应也具有螺旋选择性, 但螺旋选择性很小.     

RAFT试剂N-咔唑二硫代甲酸1,4-对二甲基苯双酯的合成及应用

以咔唑和对二氯甲基苯为原料, 合成了以咔唑为Z基团的双功能团RAFT聚合链转移试剂N-咔唑二硫代甲酸1,4-对二甲基苯双酯(PXCBD). 以PXCBD为链转移试剂, 以苯乙烯、丙烯酸甲酯及N,N-二丁基丙烯酰胺为单体, 考察了PXCBD在RAFT聚合中合成多嵌段共聚物上的应用, 并研究了PXCBD及由其合成的聚合物的荧光特性. 研究结果表明, PXCBD是一种性能优异的双功能团RAFT聚合链转移试剂, 可用于合成特殊结构并且带有荧光标识的功能高分子材料.     

富马酸二异丙酯—富马酸二正庚酯共聚物的合成与气体透过性能

自Bengough等用自由基引发聚合的方法首次得到了较高分子量的聚富马酸二乙酯后,有关富马酸酯(DRFs)类单体的聚合反应及其结构性能已进行了许多研究。结果表明,这类单体的聚合物在聚合反应活性、聚合物结构及性能等方面均有某些独特的性质,如聚富马酸二异丙酯(PDiPF)和聚富马酸二特丁酯(PDtBF)两种聚合物具有良好的氧氮透过性。我们曾研究十几种DRFs单体的聚合反应,得出非正烷基酯基的单体如富马酸二异丙酯(DiPF),富马     

ATRP法合成二十元、二十八元线形环化聚合物

采用以甲苯为聚合介质的ATRP聚合体系,以双甲基丙烯酸二醇酯为单体,合成了具有二十和二十八元环的线形环化聚合物,聚合物具有窄分子量分布.聚合动力学显示随着链长的增加,环化反应速率变慢.根据聚合物的1H-NMR谱图、由1H-NMR端基分析得到聚合度DPNMR、以及GPC图谱结果,证实获得了线形环化聚合物.TGA测试结果表明2种聚合物的起始分解温度均大于372℃,具有比PMMA更好的热稳定性.     

RAFT聚合法合成聚丙烯酰胺基偶氮苯的研究

以二硫代苯甲酸苄酯(BDTB)为链转移剂,偶氮二异丁腈(AIBN)为引发剂,丙烯酰胺基偶氮苯(AAAB)为单体,DMF为溶剂,利用可逆加成-断裂链转移(RAFT)聚合法合成了聚丙烯酰胺基偶氮苯(PAAAB),并考察了聚合温度和链转移剂浓度对聚合反应的影响。通过FT-IR、1 H-NMR、GPC等对链转移剂和聚合物结构进行了表征。结果表明:聚合反应动力学曲线呈良好的线性关系,分子量分布窄;随着[BDTB]/[AIBN]比例的增大,聚合速率和分子量下降,分子量分布变窄。     

2-芳甲酰基甲亚基丙二酸酯与Corey叶立德的反应

研究了2-芳甲酰基甲亚基丙二酸酯与Corey叶立德的反应.1.0equiv.的三甲基碘化亚砜与2.5equiv.氢化钠在N,N-二甲基甲酰胺(DMF)溶剂中制得的Corey叶立德,与2-芳甲酰甲亚基丙二酸酯在-23℃条件下通过亲核加成/消除过程得到2-(1-芳甲酰基乙烯基)丙二酸酯; 2.2 equiv.的三甲基碘化亚砜与5.0 equiv.氢化钠在DMF溶剂中制得的Corey叶立德,与2-芳甲酰甲亚基丙二酸酯在-23～0℃条件下通过亲核加成/消除/加成/环丙烷化过程得到2-(1-芳甲酰基环丙基)丙二酸酯;1.1equiv.的三甲基碘化亚砜与5.0equiv.碳酸钾在DMF溶剂中制得的Corey叶立德,与2-芳甲酰甲亚基丙二酸酯在0℃条件下通过亲核加成/环丙烷化过程得到2-芳甲酰基-1,1-环丙烷二羧酸酯.这三种过程可以通过简单调节碱及其用量以及反应温度等条件得到高选择性控制.     

联苯双酯的荧光性质及其分析应用

研究联苯双酯的荧光性质,并建立用荧光光度法测定联苯双酯滴丸中联苯双酯含量的方法.样品用乙醇超声提取,过滤,取续滤液,在室温下用乙醇作溶剂直接测定荧光强度计算联苯双酯的含量,并用RP-HPLC测定的结果作对照.实验表明,联苯双酯有较强的荧光特性,最大激发波长和发射波长分别在282 nm和388 nm;质量浓度在0.24～3.4 mg/L范围内,荧光强度与浓度有良好的线性关系,检出限为(3σ/k) 0.010 mg/L,对2.4 mg/L的联苯双酯测定的相对标准偏差为1.1% (n=10).方法用于联苯双酯滴丸中联苯双酯含量的测定,相对标准偏差RSD (n=5)在0.83%～2.8%,与RP-HPLC测定结果相比,无论是精密度还是准确度不存在显著差异.方法已用于联苯双酯滴丸中联苯双酯含量的测定.     

用双硫酯链转移法合成嵌段聚合物

研究了以双硫酯为链转移剂进行的均聚和嵌段共聚物的合成 .首先合成大分子链转移剂 ,得到分子量可控、多分散性系数较小的均聚物PMMA、PBMA、PEMA、PEA、PBA、PMA、PSt,多分散性系数一般小于 1 30 .在相同的条件下 ,甲基丙烯酸酯类的聚合速度最快 ,苯乙烯其次 ,丙烯酸酯类最慢 .用末端带有双硫酯基团的PSt、PBMA、PBA为链转移剂 ,加入多种第二单体聚合得到实测分子量与理论分子量接近 ,且多分散性系数较小的两嵌段聚合物 .在链转移剂和引发剂的比例为 3∶1～ 6∶1的范围内 ,聚苯乙烯同样可以作为第一嵌段得到和其它酯类单体的两嵌段聚合物 .1 H NMR方法证明了聚合物的末端带有双硫酯基团 .嵌段聚合时必须加入微量的自由基引发剂以形成大分子自由基 ,达到较好的控制聚合效果     

Thermal stability of aromatic polyesters prepared from diphenolic acid and its esters

The thermal performance of aromatic polyesters (poly(DPA-IPC), poly(MDP-IPC) and poly(EDP-IPC)) prepared from isophthaloyl chloride (IPC) with diphenolic acid (DPA) and its esters were studied with DSC and TG, and the decomposition mechanism of poly(DPA-IPC) were investigated using FTIR and integrated TG/FTIR analyses. As compared with ordinary aromatic polyesters, poly(DPA-IPC) has lower glass transition temperature (159 °C) and much lower thermal stability. It starts to decompose at about 210 °C and is characterized by two-stage thermal decomposition behavior, with active energies of decomposition of 206 kJ/mol and 389 kJ/mol, respectively. The analyses of the decomposition process and products indicate that the pendent carboxyl groups in poly(DPA-IPC) are responsible for its low thermal stability. Accordingly, a decomposition mechanism for the first stage is proposed. With this knowledge in mind, we capped the carboxyl groups in DPA with methyl and ethyl groups to prepare poly(MDP-IPC) and poly(EDP-IPC) from methyl diphenolate and ethyl dipenolate. As expected, these two polymers exhibit obviously improved thermal stability, with onset decomposition temperature of about 300 °C.     

Preparation and properties of polyesters and copolyesters based on 4-methyl-2,4-bis (p-hydroxyphenyl)-1-pentene

4-Methyl-2,4-bis (p-hydroxyphenyl)-1-pentene (MBHPP) was prepared from thermal cracking of bisphenol A (BPA). Unsaturated polyesters were synthesized from the polycondensation of MBHPP with diacid chlorides. Three synthetic routes—solution, interfacial, and melt polycondensation—were employed. MBHPP-polyesters with higher molecular weights were obtained by the interfacial polycondensation reaction. During the preparation of MBHPP-polysters, the products usually contain some insoluble gel, which is probably caused by the crosslinking reaction of the vinyl groups of MBHPP in the aqueous NaOH. Thus, a modified interfacial polycondensation method was proposed, in which both of the bisphenol MBHPP and diacid chloride were dissolved in organic phase and then the solution was stirred with an aqueous NaOH solution to promote the polycondensation. This method reduced the time of MBHPP present in the alkali and produced polymers with higher inherent viscosity and lower gel fraction. The effects of some variables, such as the nature of porganic solvents and phase transfer agents and the concentration of reactants, on the modified interfacial polycondensation of MBHPP with the mixture of equal parts of isophthaloyl and terephthaloyl chloride [IPC/TPC (50/50)] were investigated in some detail. Copolyesters of mixed bisphenols of BPA/MBHPP with IPC/TPC (50/50) were also prepared and characterized.     

Interfacial Polycondensation in Aqueous and Non-Aqueous Systems

Abstract

Interfacial polycondensation in aqueous and non-aqueous systems has been investigated in order to synthesize various polyamides having functional groups. Rigid aromatic polyamides having pyridine moieties (PPy) were synthesized by interfacial polycondensation using an aqueous system and the solution properties of PPy in concentrated sulfuric acid were investigated in terms of solution viscosity and lyotropic behavior. Interfacial polycondensation in a non-aqueous system using two immiscible solvents was found to be useful for the synthesis of aromatic polyesters and copolyesters.     

Thermally Crosslinkable and Chemically Modifiable Aromatic Polyesters Possessing Pendant Propargyloxy Groups

New aromatic (co)polyesters containing pendant propargyloxy groups were synthesized by phase transfer‐catalyzed interfacial polycondensation of 5‐(propargyloxy)isophthaloyl chloride (P‐IPC) and various compositions of P‐IPC and isophthaloyl chloride with bisphenol A. FTIR and NMR spectroscopic data, respectively, revealed successful incorporation of pendant propargyloxy groups into (co)polyesters and formation of (co)polyesters with desired compositions. (Co)polyesters exhibited good solubility in common organic solvents such as chloroform, dichloromethane, and tetrahydrofuran and could be cast into transparent, flexible, and tough films from chloroform solution. Inherent viscosities and number average molecular weights of (co)polyesters were in the range 0.77–1.33 dL/g and 43,600–118,000 g/mol, respectively, indicating the achievement of reasonably high‐molecular weights. The 10% weight loss temperatures of (co)polyesters were in the range 390–420 °C, demonstrating their good thermal stability. (Co)polyesters exhibited T_g in the range 146–170 °C and T_g values decreased with increase in mol % incorporation of P‐IPC. The study of non‐isothermal curing by DSC indicated thermal crosslinking of (co)polyesters via propargyloxy groups. The utility of pendant propargyloxy group was demonstrated by post‐modification of the selected copolyester with 1‐(4‐azidobutyl)pyrene, 9‐(azidomethyl)anthracene, and azido‐terminated poly(ethyleneglycol) monomethyl ether via copper(I)‐catalyzed Huisgen 1,3‐dipolar cycloaddition reaction. FTIR and ¹H NMR spectra confirmed that click reaction was quantitative. © 2018 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2019 , 57, 588–597     

Phenazasiline-containing polyamides and polyesters

A Phenazasiline ring was incorporated into a polymer backbone by polycondensation of 2,8-dichloroformyl-5,10-dihydro-5-methyl-10,10-diphenylphenazasiline (V) with aromatic diamines or bisphenols, and phenazasiline-containing polyamides and polyesters were obtained. The polyamides were prepared by low-temperature solution polycondensation in N-methyl-2-pyrrolidone (NMP) in the presence of lithium chloride. The polyesters were synthesized by interfacial polycondensation in a mixture of 1,2-dichloroethane and aqueous alkali in the presence of tetrabutylammonium chloride as an accelerator. These reaction conditions gave the corresponding polymers with high viscosities. The phenazasiline-containing polyamides exhibited good solubilities in polar aprotic solvents such as dimethylformamide, dimethylacetamide, and NMP, and also in m-cresol, although the polyesters showed limited solubilities in organic solvents. Under nitrogen, the phenazasiline-containing polyamides and polyesters showed little degradation below 400°C and had good heat resistance.     

Synthesis of polyester by direct polycondensation with triphenylphosphine

Direct polycondensation reactions of various dicarboxylic acids and diols were carried out at room temperature with triphenylphosphine and polyhalo compounds to obtain polyesters in good yield. Reaction conditions including solvent, temperature, concentration of monomer, amount of reagents, and effect of matrix on direct polycondenation were investigated. A combination of triphenylphosphine and hexachloroethane was found to be satisfactory for the polyester synthesis. The addition of matrix polymers such as poly(4-vinylpyridine) in the reaction system enhanced the direct polycondensation reaction, and a polyester with a solution viscosity of 2.24 was obtained from bisphenol A and isophthalic acid under the optimum condition.     

Synthesis and characterization of new polyesters based on 2,5-bis[(4-chloro carboxyanilino) carbonyl] pyridine and aromatic diols

<正>Six new polyesters 7a-f were synthesized through the solution polycondensation reaction of diacid chloride 5 with six aromatic diols 6a-f in N,N-dimethyl acetamide(DMAc) as solvent in the presence of pyridine as base.The polycondensation reaction produced a series of novel polyester containing pyridyl moiety in the main chain in high yields with inherent viscosities between 0.35 and 0.54 dL/g.The resulted polymers were fully characterized by means of FT-IR spectroscopy,elemental analyses,inherent viscosity and solubility tests.Thermal properties of these polymers were investigated by using thermal gravimetric analysis(TGA) and differentional thermal gravimetric(DTG).The glass-transition temperatures of these polyesters were recorded between 130 and 170℃by differential scanning calorimetry(DSC) and the 10%weight loss temperatures were ranging from 390 to 450℃under nitrogen.     

New thermally stable polyesters based on 2,5-pyridinedicarbonyl dichloride and aromatic diols:Synthesis and characterization

Six new thermally stable polyesters(4a-f) were synthesized through the solution polycondensation reaction of 2,5-pyridine dicarbonyldichloride(2) with six aromatic diols in N,N'-dimethyl acetamide(DMAc) solution and in the presence of pyridine as a base.The polycondensation reactions produce a series of new polyesters(4a-f) in high yields,and inherent viscosity between 0.30 and 0.55 dL/g.The resulting polyesters were characterized by elemental analysis,viscosity measurements,thermal gravimetric analysis(...     

Design and Synthesis of Aromatic Polyesters Bearing Pendant Clickable Maleimide Groups

A bisphenol bearing pendant maleimide group, namely, N‐maleimidoethyl‐3, 3‐bis(4‐hydroxyphenyl)‐1‐isobenzopyrrolidone (PPH‐MA) was synthesized starting from phenolphthalein. Aromatic (co)polyesters bearing pendant maleimide groups were synthesized from PPH‐MA and aromatic diacid chlorides, namely, isophthaloyl chloride (IPC), terephthaloyl chloride (TPC), and 50:50 mol % mixture of IPC and TPC by low temperature solution polycondensation technique. Copolyesters were also synthesized by polycondensation of different molar proportions of PPH‐MA and bisphenol A with IPC. Inherent viscosities and number‐average molecular weights of aromatic (co)polyesters were in the range of 0.52–0.97 dL/g and 20,200–32,800 g/mol, respectively indicating formation of medium to reasonably high‐molecular‐weight polymers. ¹³C NMR spectral analysis of copolyesters revealed the formation of random copolymers. The 10% weight loss temperature of (co)polyesters was found in the range 470–484 °C, indicating their good thermal stability. A selected aromatic polyester bearing pendant maleimide groups was chemically modified via thiol‐maleimide Michael addition reaction with two representative thiol compounds, namely, 4‐chlorothiophenol and 1‐adamantanethiol to yield post‐modified polymers in a quantitative manner. Additionally, it was demonstrated that polyester containing pendant maleimide groups could be used to form insoluble crosslinked gel in the presence of a multifunctional thiol crosslinker. © 2018 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2019 , 57, 630–640     

聚对苯二甲酸戊二酯的性能研究

采用酯化法合成聚对苯二甲酸戊二酯 (PPT) ,利用IR与1H NMR对其结构进行表征 ,对其特性粘数的测定方法进行了研究 ,得到k +k′约为 0 5,即PET切片特性粘数的测试方法同样适用于PPT .用差热扫描量热法 (DSC)研究了PPT的结晶能力 ,并进行了等温结晶动力学分析 ,结果表明PPT的结晶速度很慢 ,需要较长的结晶时间 .热失重法 (TG)比较了PPT与聚对苯二甲酸丙二酯 (PTT)的热降解过程 ,结果表明尽管二者熔点相差很大 ,但热分解温度相近 .