稀土催化丁二烯-异戊二烯共聚合过程中的原位环化反应

稀土催化剂;环聚反应;稀土催化丁二烯-异戊二烯共聚合过程中的原位环化反应     

钕-铝双金属配合物催化异戊二烯聚合的原位环化反应

环化聚异戊二烯 (CPIP)具有优良的光敏性、较好的耐热性和力学性能 ,在光刻胶、胶粘剂、橡胶改性等方面得到广泛应用 [1,2 ] .CPIP可按阳离子机理经单体环聚或聚合物环化两种方法合成 .我们 [3]最近提出一种直接从单体出发在稀土催化聚合过程中引入烯丙基氯原位合成 CPIP的方法 .本文在此基础上 ,以三异丙氧基钕 -三乙基铝 -一氯二乙基铝均相体系中分离出的钕 -铝双金属配合物作为单组分催化剂 ,简化聚合体系 ,以便直观地考察氯化物、烷基铝等的作用 ,揭示稀土催化 IP聚合原位环化反应的过程 .1　实验部分　　 CPIP的合成参见文献 […     

稀土催化丁二烯顺式聚合过程中的环化改性

采用ＮｄＣｌ３·３ｉ－ＰｒＯＨ－ＡｌＥｔ３稀土催化剂进行丁二烯的顺式聚合，在聚合过程中引入烯丙基氯，进行分子内环化反应以及单体的环聚反应．考察了稀土催化剂用量、ｎ（烯丙基氯）／ｎ（ＡｌＥｔ３）、环化时间、反应温度、单体浓度等对环化反应的影响，并对产物进行了红外光谱、核磁共振光谱的表征     

单茂钪催化非共轭双烯环化聚合及与乙烯共聚合的研究

以(C5Me4SiMe3)Sc(CH2C6H4NMe2-o)2和[Ph3C][B(C6F5)4]组成的单茂钪催化体系催化非共轭双烯均聚合及与乙烯共聚合,考察了聚合条件及非共轭双烯结构对聚合活性、产物分子量和微结构的影响.单茂钪催化体系中,单体浓度、聚合温度、聚合溶剂以及烷基铝试剂对1,5-己二烯的聚合活性和选择性以及聚合产物的分子量和分子量分布均有较大影响.室温甲苯溶剂中,单茂钪可以催化1,5-己二烯,1,6-庚二烯,1,7-辛二烯,1,9-癸二烯四种非共轭双烯聚合获得相应的聚合物;除1,9-癸二烯聚合获得不溶的交联聚合物外,其它非共轭双烯聚合均获得可溶的环烯烃聚合物.1,5-己二烯聚合形成亚甲基-1,3-环戊基(MCPN)五元环和四元环开环形成的3-乙烯基四亚甲基(VTM)结构单元.1,6-庚二烯聚合完全环化形成亚甲基-1,3-环己基(MCHX)六元环和乙烯基-1,2-环戊基(ECPN)五元环结构单元,1,7-辛二烯聚合形成亚甲基-1,3-环庚基(MCHP)七元环结构单元和未环化的悬挂己烯(HEB)结构单元.室温1.01×105Pa乙烯压力下,单茂钪催化体系还可以快速催化非共轭双烯1,5-己二烯,1,6-庚二烯,1,7-辛二烯,1,9-癸二烯与乙烯共聚合,获得含有环状结构单元、悬挂双键结构单元和聚乙烯嵌段的无规共聚物.在单茂钪催化非共轭双烯均聚合及与乙烯共聚合中,非共轭双烯的链长直接影响了其聚合活性和选择性.     

等规聚苯乙烯与聚(乙烯/丙烯)嵌段共聚物的研究(Ⅰ)──一步法嵌段共聚合反应

用自制的稀土化合物改性的高效钛系载体催化剂(SN－1),以顺序加料一步法进行苯乙烯与乙烯/丙烯混合单体的嵌段共聚合反应．通过实验找出典型的共聚合条件为：甲苯为溶剂;催化剂浓度为1．5～1．6mmol/L;铝钛摩尔比为20;聚合温度65℃．先使苯乙烯预聚一定时间,然后连续通入乙丙混合气体．共聚合产物中iPS链段的含量随苯乙烯单体预聚合时间的延长而增加．     

非茂钯催化剂催化乙烯/丙烯/ω-Cl-α-乙烯基单体三元共聚合的研究

本文探索了乙烯/丙烯/极性单体三元共聚物的合成方法.乙烯/丙烯/ω-Cl-α-乙烯基单体三元共聚物由于分子中引入了ω-Cl-α-乙烯基极性单体,改变了乙烯丙烯共聚物的化学惰性.我们采用催化剂Cat.L-Pd配位催化乙烯/丙烯/ω-Cl-α-乙烯基单体三元共聚合,合成了极性三元无规共聚物.探讨了催化剂结构、聚合条件对三元共聚合行为的影响,并优化了聚合条件.采用红外光谱(FTIR)、核磁共振碳谱(氢谱)(~(13)C(~1H)NMR)、示差扫描量热(DSC)和高温凝胶渗透色谱(GPC)等方法研究了共聚物的结构与性能.FTIR与~(13)C(~1H)NMR结果表明,催化剂Cat.L-Pd能够有效催化乙烯/丙烯/ω-Cl-α-乙烯基单体三元共聚合,共聚物中ω-氯代极性单体的插入量达3.6 mol%.极性单体不发生均聚合反应,但能够有效参与乙烯和丙烯的共聚合反应,形成三元无规共聚物.丙烯能够发生均聚合反应,但是不能形成聚丙烯长链段,主要发生乙烯与丙烯共聚合反应.乙烯最易发生聚合反应,并能够形成较长链段的聚乙烯.共聚物的Mw高于2×10~5g/mol.分子量分布在1.6～3.0,说明该类催化剂催化乙烯/丙烯/ω-Cl-α-乙烯基单体三元共聚合行为遵循单中心聚合机理.     

等规聚苯乙烯与聚（乙烯／丙烯）嵌段共聚物的研究（I）——一…

用自制的稀土化合物改性的高效钛系载体催化剂（ＳＮ－１），以顺序加料一步法进行苯乙烯与乙烯／丙烯混合单体的嵌段共聚合反应。通过实验找出典型的共聚合条件为：甲苯为溶剂；催化剂浓度为１．５￣１．６ｍｍｏｌ／Ｌ，铝钛摩尔比为２０；聚合温度６５℃，先使苯乙烯预聚一定时间，然后连续通入乙丙混合气体，共聚合产物中ｉＰＳ链段的含量随苯乙烯单体预聚合时间的延长而增加。     

镍催化转移缩聚合成全氟环丁基芳基醚聚合物

研究了通过镍催化转移缩聚的方法来合成全氟环丁基芳基醚聚合物.首先,我们以对溴苯酚和1,2-二溴四氟乙烷为起始原料,通过两步反应得到对溴三氟乙烯基芳基醚,进一步加热环化二聚得到单体1,2-二(4-溴苯氧基)六氟环丁烷.该二聚物再与异丙基格氏试剂发生镁交换反应,生成格氏试剂中间体,在催化剂Ni(dppe)Cl2的存在下发生镍催化转移缩聚生成聚合物.研究了反应时间、温度和单体投料比对催化缩聚反应的影响.     

基于C–H活化的炔烃聚合反应合成多功能稠(杂)环聚合物

稠(杂)环聚合物是一类重要的功能聚合物,因其优异的光电特性而被广泛应用于光电领域.这类聚合物的传统制备方法往往需要用到修饰有复杂官能团的稠(杂)环单体,这些单体种类有限且合成难度大,导致稠(杂)环聚合物的发展受到限制. C–H活化过程的发现与提出为利用惰性的C–H键作为潜在官能团提供了可能,有效避免了对单体进行复杂修饰的要求,大大扩增了单体的种类和来源.基于C–H活化的炔烃环化聚合反应,能够在聚合物骨架中原位直接形成稠(杂)环结构,具有原料简单易得、聚合效率高、产物结构丰富等诸多优势,因此受到广泛关注.本文分类总结了基于C–H活化的炔烃环化聚合领域的最新进展,包括合成手段和所得聚合物的性质与功能介绍,并对该领域的未来发展方向进行了展望.     

三（环戊基茚基）钐配合物（C5H9C9H6）3SmCl^—Li^＋（THF）4的合成与晶体结构

稀土配合物能使极性和非极性单体聚合[1] .虽然目前已测定了几乎所有的三 (环戊二烯基 )稀土配合物及部分三 (取代环戊二烯基 )稀土配合物的晶体结构 ,但有关三 (茚基 )稀土配合物的报道较少 .第一个三 (茚基 )稀土配合物是无水三氯化稀土与 3倍物质的量的茚基钠 C9H7Na在四氢呋喃中反应而得 ,但未报道其晶体结构[2 ] .后来用同样的反应却分离出以氯为桥的二聚体离子对配合物[Na( THF) 6][Ln( η5- C9H7) 3μ( Cl) Ln( η5- C9H7) 3]( Ln=Nd,Sm) [3] .无水三氯化稀土与 Mg( C9H7) 2 或C9H7K等物质的量反应则生成非溶剂化的 ( C9H7…     

Die stufenweise Syntheseo,o′-methylenverbrückter Cyclohexamerer mitp-Kresol- oderP-Kresol- und 4-tert-Butylphenol-Bausteinen Vergleich mit ähnlich strukturierten Kettenoligomeren

Two phenolic alcohols with six phenolic units in their molecules have been obtained by stepwise syntheses starting from simple phenolic derivatives. The phenolic alcohols were cyclized in a one step cyclization by boiling in a very diluted acetic acid solution. A two step cyclization of a phenolic alcohol with three phenolic units to a cyclohexamer proceeds only with poor yields. The cyclic compounds were compared with chainlike oligomers containing six phenolic units in their molecules.

Herrn Prof. Dr.H. F. Mark mit allen guten Wünschen zum 85. Geburtstag gewidmet.     

裂解色谱法研究环化顺—1,4—丁二烯—异戊二烯无规共聚物

如同顺-1,4-聚丁二烯(PBd)和聚异戊二烯(PIP),在一定的催化条件下,顺-1,4-丁二烯-异戊二烯无规共聚物(PBI,简称丁戊无规共聚物)可生成环化顺-1,4-丁戊无规共聚物(CP-BI)。作者曾报道用裂解色谱法表征环化顺-1,4-聚丁二烯(CPBd),本文对不同组成的CPBI和PBI进行了裂解色谱比较研究。 表1所列试样由实验室合成。用CDS pyro-probe 190型裂解器,SP-2305E型气相色谱仪,FID。裂解温度700℃,裂解时间5秒,色谱柱4mm×3m不锈钢柱,填充20%SE-30固定相(101白色担体),柱温106℃,载气氮气40mL/min。试样量约30μg,放于石英管内,后者再插入     

Polymerizations of butadiene,isoprene, and 2,3-dimethylbutadiene by Gd(OCOCCl3)3–(i-Bu)3Al–Et2AlCl and the cis polymerization mechanism for dienes

Homopolymerizations of butadiene (BD), isoprene (IP), and 2,3-dimethylbutadiene (DMBD) were carried out by a Gd(OCOCCl₃)₃-based catalyst, to investigate the effects of the energy levels of the monomers or the sterical factor of the methyl substituents on the polymerizability and the cis-selectivity of the monomers. The order of the polymerizability at 50°C was as follows: BD (4.5 kg of polymer/(mol of Gd h)) ∼ IP (4.8) > DMBD (0.6). On the other hand, the cis-selectivity of the polymers was as follows: BD (98%) > IP (94%) > DMBD (35%). These results suggest that the terminal BD and IP units are controlled by the cis configuration by the coordination between the penultimate cis-vinylene unit and the catalyst metal, whereas the penultimate DMBD unit unfavorably controls the terminal DMBD unit to the cis-1,4 configuration through the back-biting coordination with difficulty by two methyl substituents compared with the penultimate BD and IP units. The validity of the back-biting coordination was examined by MO calculation with σ-allylnickel complexes. According to the formation energy with respect to the BD–BD diad, the cis–cis form is somewhat preferable to the trans–cis form through the coordination of the penultimate BD unit by ΔE = 0.028 au (ca. 17.6 kcal/mol). © 1998 John Wiley & Sons, Inc. J. Polym. Sci. A Polym. Chem. 36: 2283–2290, 1998     

Intramolecular friedel‐crafts cyclization and subsequent hydrogenation of styrene‐isoprene random copolymers prepared by anionic polymerization for thermally‐resistant and optical applications

To synthesize novel thermally and optically high‐performing thermoplastics from commodity monomers, random styrene (St)‐isoprene (Ip) rubbers (r‐SIRs) prepared by anionic copolymerization were subjected to intramolecular Friedel‐Crafts cyclization and subsequent hydrogenation via a sequence of simple postpolymerization modifications. The CF₃SO₃H‐catalyzed Friedel‐Crafts alkylation of r‐SIR afforded cyclized r‐SIR (C‐r‐SIR) via the predominant formation of bicyclic tetrahydronaphthyl units to give thermoplastics with a high glass transition temperature (T_g ～130 °C), good mechanical properties, and good transparency. Subsequent hydrogenation of the small amount of remaining C?C double bonds in the uncyclized Ip units and cyclized Ip‐Ip units yielded hydrogenated C‐r‐SIR (HC‐r‐SIR) and increased the degradation temperature by about 15 °C (T_d5 ≥ 380 °C). These HC‐r‐SIRs display good flexural moduli and strength, good transparency, and refractive indices similar to those of C‐r‐SIR. The birefringence of HC‐r‐SIR was successfully tuned by adjusting the comonomer content to obtain near‐zero birefringence high‐performance plastics. © 2012 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem, 2012     

Chiral Lewis base-assisted Brønsted acid (LBBA)-catalyzed enantioselective cyclization of 2-geranylphenols

Chiral Lewis base-assisted Br?nsted acids (Chiral LBBAs) have been designed as new organocatalysts for biomimetic enantioselective cyclization. A salt of a chiral phosphonous acid diester with FSO(3)H catalyzes the enantioselective cyclization of 2-geranylphenols to give the desired trans-fused cyclized products with high diastereo- and enantioselectivities (up to 98:2 dr and 93% ee).     

Acid-catalyzed cyclization of vinylsilanes bearing an amino group. Stereoselective synthesis of pyrrolidines

[reaction: see text] In the presence of an acid catalyst, vinylsilanes 1 bearing an amino group protected by an electron-withdrawing group were smoothly cyclized to 2-(silylmethyl)pyrrolidines 2. This cyclization was utilized for the stereoselective synthesis of 2,n-disubstituted pyrrolidines (n = 3-5). The cyclized products could be converted to the corresponding alcohols by oxidative cleavage of the carbon-silicon bond with TBAF and H2O2.     

环化顺1,4丁二烯异戊二烯无规共聚物的表征

<正> 已知,聚异戊二烯或聚丁二烯等1,3-双烯聚合物可在路易斯酸催化剂作用下按阳离子型机理进行分子内环化反应,所得“环化橡胶”,做为可光敏固化的新材料,在光刻胶、光保护膜、胶粘剂等方面得到广泛应用。文献还表明,环化顺1,4聚双烯产物比环化其它结构的聚双烯产物具更好的使用性能。鉴于合成高分子材料中共聚物往往较均聚物呈现     

共轭双烯与丙烯酸甲酯交替共聚物的~(13)C-NMR谱研究

用~(13)C-NMR方法研究了丁二烯(BD)-丙烯酸甲酯(MA)、异戊二烯(IP)-MA和氯丁二烯(CP)-MA交替共聚物(分别简称为PBM、PIM和PCM)的联接方式和微观结构。在PBM中,BD单元以反-1,4-结构存在,并有少量的顺-1,4-和1,2-结构,其比例为88:7:5;在PIM和PCM中,IP与CP单元也主要以反-1,4-结构存在,与MA以“头-头”方式相连接。在PCM中还有少量CP-CP相连接的结构,交替度较低,而PBM和PIM则完全是交替结构。     

Efficient and regioselective 9-endo cyclization of α-carbamoyl radicals

With the promotion of Lewis acid BF(3)?OEt(2), various N-(hex-5-enyl)-2-iodoalkanamides underwent efficient and regioselective 9-endo iodine-atom-transfer radical cyclization reactions at room temperature. The cyclized products were readily converted to the corresponding azonan-2-ones by reduction with Bu(3)SnH or to hexahydroindolizin-3(5H)-ones by treatment with aqueous Na(2)CO(3) in a one-pot, two-stage manner.     

Pt- and Au-catalyzed oxidative cyclization of 2-ethenyl-1-(prop-2'-yn-1'-ol)benzenes to naphthyl aldehydes and ketones: catalytic oxidation of metal-alkylidene intermediates using H2O and H2O2

2-Ethenyl-1-(prop-2'-yn-1'-ol)benzenes was cyclized through catalytic oxidation with PtCl(2)/CO/H(2)O and PEt(3)AuCl/H(2)O(2); the metal-naphthylidene intermediates were identified and oxygenated with water and H(2)O(2), respectively; for the efficiency of cyclization, the Au catalytic system is superior to that of the PtCl(2)-catalysis because of its compatibility toward diverse alcohol substrates including both internal alkynes and terminal alkynes.