甲基丙烯酸丁酯和苯乙烯的原子转移自由基共聚

研究了甲基丙烯酸丁酯（ＢＭＡ）和苯乙烯（Ｓ）这两种不同极性单体的原子转移自由基嵌段共聚和无规共聚,得到了实测分子量与理论分子量相近,分子量分布较窄的嵌段共聚物和无规共聚物．聚合过程中分子量和单体转化率成比例增加,多分散性指数变化不大．用１Ｈ ＮＭＲ法测定共聚组成,Ｋｅｌｅｎ Ｔｕｄｏｓ法计算竞聚率．得到ｒＳｔ＝０９１,ｒＢＭＡ＝０３２．     

CONTROLLED SEQUENTIAL AND RANDOMRADICAL COPOLYMERIZATION OF STYRENE AND BUTYL METHACRYLATE BY ATOM TRANSFER RADICAL POLYMERIZATION

1.INTRODUCTIONAgeneralmethodfortheblockandstahsticalcopolymerizationofvinylmonomerstogivelow-polydisperSitypolymerswithaccuratecontrolovermolecularweightandchainendshaslOngbeenagoalofsynthehcPOlymerchemists.Livingpolymerizahonsappearedtobethebesttpeboquetoreachthistarget'.Matyjaszewskifi31hasreportedtheuseofatomtransferradicaladdihonchemistry,asdevelopedforcarbon-carbonbondformationinorganicsynthesis,tomediateatomtfansferradicalpolymerization(AW)forthecontrolled"living.'polymerizationof…     

N-取代马来酰亚胺和苯乙烯的原子转移自由基共聚合

近来,以卤代烷、铜（Ⅰ）卤素盐和２,２ 联吡啶体系引发苯乙烯可进行活性聚合,即原子转移自由基聚合（ＡＴＲＰ）,得到指定分子量和窄分子量分布的聚合物［１］,开辟了活性聚合的一个新领域,引起了广泛的关注．利用ＡＴＲＰ方法,对合成较窄的分子量分布的均聚物...     

甲基丙烯酸甲酯的原子转移自由基悬浮聚合

以 1 苯基氯乙烷为引发剂 ,氯化亚铜为催化剂 ,2 ,2 联吡啶为配体 ,外加搅拌 ,氮气保护下进行了甲基丙烯酸甲酯 (MMA)在 80℃下的原子转移悬浮聚合 .结果表明 ,聚合反应符合对单体浓度为一级的动力学关系 .经计算聚合体系的增长自由基浓度为 5 .74× 10 - 8mol L .聚合物分子量随转化率呈线性增加 ,分子量分布较窄 ,Mw Mn 在 1.37～ 1.40之间 .还以AIBN为引发剂 ,在三氯化铁和三苯基膦存在下进行了MMA的反向原子转移本体和悬浮聚合研究 .结果证明本体聚合具有好的可控特征 ,分子量随转化率呈线性增长 ,分子量分布指数在 1.2 7～ 1.31之间 .聚合反应速率较快 ,聚合体系中的增长自由基浓度较高 ,为 1.6 4× 10 - 7mol L .而在此催化体系下的悬浮聚合则完全失去了活性特征     

富马酸亚铁催化甲基丙烯酸甲酯活性自由基聚合的研究

以富马酸亚铁为催化剂,以2-溴代异丁酸乙酯为引发剂,在90℃下进行甲基丙烯酸甲酯的原子转移自由基本体聚合及溶液聚合.聚合物的数均相对分子质量随单体转化率的增加而线性增加,与时间呈良好线性关系,本体聚合时分子量分布 (PDI) 在1.5～1.7之间,溶液聚合时PDI＜1.5.通过聚合物扩链反应和端基分析,表明富马酸亚铁催化原子转移自由基聚合反应具有活性(可控)聚合的特征.     

富马酸亚铁催化甲基丙烯酸甲酯活性自由基聚合的研究

以畜马酸亚铁为催化剂,以2-溴代异丁酸乙酯为引发剂,在90℃下进行甲基丙烯酸甲酯的原子转移自由基本体聚合及溶液聚合.聚合物的数均相对分子质量随单体转化率的增加而线性增加,与时间呈良好线性关系,本体聚合时分子量分布(PDI)在1.5～1.7之间,溶液聚合时PDI＜1.5.通过聚合物扩链反应和端基分析,表明富马酸亚铁催化原子转移自由基聚合反应具有活性(可控)聚合的特征.     

α,α-二溴甲苯引发的苯乙烯原子转移自由基聚合研究

自从Ｍａｔｙｊａｓｚｅｗｓｋｉ等[1,2 ] 发现原子转移自由基聚合 (ＡＴＲＰ)以来 ,寻求新的双多官能引发剂是该领域的重要研究方向之一[3～ 7] .2 0 0 0年 ,我们[8]曾报道了α ,α 二溴乙酸乙酯可作为丙烯酸酯ＡＴＲＰ的双官能引发剂 ,并基于其两端增长的活性聚合性质合成了ＰＳ ｂ ＰＢＡ ｂ ＰＳ和ＰＭＭＡ ｂ ＰＢＡ ｂ ＰＭＭＡ两种三嵌段共聚物 .与此同时 ,Ｈｏｃｋｅｒ等[9] 通过比较氯化苄与α ,α 二氯甲苯引发的苯乙烯ＡＴＲＰ的聚合速度 ,认为α ,α 二氯甲苯是苯乙烯ＡＴＲＰ的双官能引发剂 .当我们参照上述结果 ,用α ,α 二…     

水分散体系中由BPO或KPS引发的苯乙烯反向原子转移自由基聚合

分别以过氧化二苯甲酰 (BPO)和过硫酸钾 (KPS)为引发剂、1 ,1 0 邻二氮菲为催化剂配体、十二烷基磺酸钠为乳化剂 ,在水分散体系中进行了苯乙烯的反向原子转移自由基聚合反应 .结果表明 ,对于BPO引发的苯乙烯乳液聚合反应 ,必须由CuBr和CuBr2 形成复合催化剂体系才能达到较好的控制效果 ,其中CuBr可以是直接加入到催化剂体系中 ,也可以是由CuBr2 与Cu0 就地快速反应生成 .CuBr迅速地与BPO反应而实现活性聚合中所谓的“快引发” ,从而有效地控制苯乙烯的聚合反应 .对于KPS引发的苯乙烯乳液聚合体系 ,反应介质的pH值对聚合有很大的影响 ,反应速度随着反应介质pH值的升高而加快 .实验结果表明 ,由两种不同引发剂引发的苯乙烯的乳液的粒径及粒径分布也有很大的差异     

REVERSE ATOM TRANSFER RADICAL POLYMERIZATION OF STYRENE WITH COPPER-BASED CATALYST

 "Living"/controlled radical polymerization of styrene was carried out with diethyl 2,3-dicyano-2,3-diphenylsuccinate (DCDPS)/CuCl₂/bipyridine (bipy) initiation system at 120℃. The molecular weights of resultant PSt increased with the monomer conversion and the polydispersities were in the range of 1.37 ～ 1.52. A linear ln([M]o/[M])versus time plot was also obtained indicating the constant concentration of growing radicals during the polymerization with this initiation system. End group analysis by ¹H-NMR spectroscopic studies showed that the end groups of the polymer obtained is cω-functionalized by a chlorine group from the catalyst and a-functionalized by a (carbethoxy-cyano-phenyl)methyl group from the fragments of the initiator. Having C1 atom at the chain end, the PSt obtained can be used as a macroinitiator to promote a chain-extension reaction with fresh St and block copolymerization reaction with a second monomer, such as methyl methacrylate, in the presence of CuC1/bipy catalyst via a conventional ATRP process.     

原子转移自由基聚合制备聚(甲基丙烯酸甲酯-b-苯乙烯)时单体聚合顺序对嵌段效率的影响

采用原子转移自由基聚合研究了聚（ 甲基丙烯酸甲酯 ｂ 苯乙烯） 嵌段共聚物的合成,实验结果表明,当先进行甲基丙烯酸甲酯的聚合,然后再进行苯乙烯的聚合时,得到了完全的嵌段共聚物;反之,如果改变单体的聚合顺序,则嵌段效率很低．用聚合物末端Ｃ—Ｘ（Ｘ＝ Ｃｌ,Ｂｒ） 键的断裂能对实验结果进行了解释．     

A NOVEL PHOTO-INITIATING SYSTEM FOR ATOM TRANSFER RADICAL POLYMERIZATION OF STYRENE

A novel photo-induced initiating system, 2, 2 - dimethoxy-2-phenylacetophenone (DMPA)/ferric tri(N,N-diethyl-dithiocarbamate) [Fe(DC)_3], was developed and used for the atom transfer radical polymerization (ATRP) of styrene intoluene. The polymerization proceeds with DMPA as photo-initiator, Fc(DC)_3 as catalyst and DC as a reversible transfergroup, while the halogen and ligands are free. Well-defined PSt was prepared and the polymerization mechanism revealed byend group analysis belongs to a reverse ATRP. Block copolymer was prepared by using thus obtained PSt as macroinitiatorand Fe(DC)_2 as catalyst under UV light irradiation via a conventional ATRP process.     

原子转移自由基聚合法合成大豆分离蛋白-g-聚甲基丙烯酸2-羟乙酯

通过酰胺化反应在大豆分离蛋白(SPI)表面引入溴原子,合成了大分子引发剂SPI-Br,以CuCl和bpy为催化体系,通过原子转移自由基聚合法(ATRP)合成了大豆分离蛋白-g-聚甲基丙烯酸2-羟乙酯(SPI-g-PHEMA).用FTIR1、3C-NMR、GPC对大分子引发剂、接枝产物和接枝物降解链进行结构表征.结果表明,得到了表面接枝聚甲基丙烯酸2-羟乙酯长链的大豆分离蛋白接枝聚合物,用紫外分光光度计(UV)、荧光分光光度计z、eta电位和透射电镜(TEM)表征了接枝产物的溶液性质和微观形态.     

ATRP法制备两亲性嵌段共聚物的研究

以α 溴代丙酸乙酯 (EPN Br)为引发剂、氯化亚铜 (CuCl)和联二吡啶 (bpy)组成的混合体系为催化剂 ,引发苯乙烯聚合 ,得到了端基为卤原子的单分散聚苯乙烯 (PS X)预聚体 .以此PS X为大分子引发剂、CuCl和N ,N ,N′ ,N″ ,N″ 五甲基二亚乙基三胺 (PMDETA) bpy的混合体系为催化剂 ,引发N ,N 二甲基丙烯酰胺(DMAA)聚合 ,得到了分子量分布较窄的聚苯乙烯 b 聚N ,N 二甲基丙烯酰胺 (PS b PDMAA)两亲性嵌段共聚物 .考察了大分子引发剂的分子质量、聚合介质及配位剂等对聚合过程的影响 .并用GPC、IR、1 H NMR等对产物进行了表征 .研究结果表明 ,该聚合反应体系符合原子转移自由基聚合的特征 .     

原子转移自由基法合成4-(4′-甲氧基苯基甲亚胺)苯酚功能化的六臂星型聚苯乙烯

星型聚合物由于其独特的构型及其粘弹性能使其可能在交联剂,离子交换聚合物,表面活性剂,增容剂,热塑性弹性体等方面得到广泛的应用.星型聚合物按其链结构可以分为,星型(嵌段)聚合物[1],星型-支化聚合物[2],星型-梳状聚合物[3].星型聚合物的合成始于20世纪50年代活性负离子聚合[     

以BPO引发苯乙烯反向ATRP水分散体系中催化剂、乳化剂等在水/油两相分配系数的测定

在以过氧化二苯甲酰(BPO)为引发剂、1,10-邻二氮菲(phen)为催化剂配体、十二烷基磺酸钠(SLS)为乳化剂,水分散体系中进行的苯乙烯(St)的反向原子转移自由基聚合体系中,系统地分析了CuBr2/phen络合物、CuBr/phen络合物、SLS和phen在St/水两相中的分配行为,发现CuBr2/phen络合物、CuBr/phen络合物的两相分配系数对温度有一定的依赖性,结合所得的两相分配系数,从理论上分析了CuBr/CuBr2/phen/BPO乳液聚合体系中的"活性"/可控乳液聚合活性种的数目,较详细的讨论了水分散体系中反向ATRP反应的机理,并通过分相后的本体聚合实验,佐证了测得的催化体系的两相分配系数具有一定的指导意义.     

ATOM TRANSFER RADICAL POLYMERIZATION OF 2,5-BIS[（4-HEXYLOXYPHENYL）OXYCARBONYL]STYRENE

A side-on liquid crystalline monomer, 2,5-bis[(4-hexyloxyphenyl)oxycarbonyl]styrene) (HPCS), was successfully polymerized via atom transfer radical polymerization (ATRP). The polymerization was catalyzed by CuBr/PMDETA in chlorobenzene at 90℃ with (1-bromoethyl)benzene as the initiator. The polymers have narrow MWD. It is the second example of mesogen-jacketed liquid crystalline polymer (MJLCP) prepared by ATRP.     

THE ATOM TRANSFER RADICAL POLYMERIZATION OF LAURYL ACRYLATE

The atom transfer radical polymerization (ATRP) of dodecyl (or lauryl) acrylate (LA) has been studied and optimized to yield polymers with predetermined molecular weights and low polydispersities. The poor solubility of the catalyst complex formed with linear tridentate amines and Cu(I)Br in both LA and the non-polar solvents required for the formed poly(lauryl acrylate) (pLA) resulted in poor control of the polymer molecular weights and high polydispersity. The use of a soluble catalyst formed by complexing copper with 4,4′-di(5-nonyl)-2,2′-bipyridine, improved both molecular weight control and polydispersities. The experimental conditions were further optimized by adding deactivating Cu(II) complex to the initial reaction mixture to compensate qualitatively for differences in the rate of termination relative to other acrylates.     

SYNTHESIS OF POLYMERS WITH AMINO END GROUPS BY ATOM TRANSFER RADICAL POLYMERIZATION

Atom Transfer Radical Polymerization (ATRP) is a controlled radical polymerization process that produces polymers with predictable molecular weights, narrow polydispersities, and well-defined halogen end groups. The key factor in the control of the polymerization process is the presence of a metal/ligand complex that provides a fast, reversible activation and deactivation of the growing polymer chains. The ligands, used to complex the metal are mostly tertiary amino compounds. However, amines can interact with the halogen end groups of the initiator molecules or of the growing chains. Our investigations concern-ing this issue indicate that under the experimental conditions used during the polymerization process, interactions of end groups with tertiary amines are negligible. Ammonia and primary amines, e.g., n-butylamine, however can react with the halogen end groups. Moreover, after the polymerization reaction they can be used as nucleophilic agents to replace the halogens by other functional end groups. The use of difunctional molecules such as ethanolamine leads to the incorporation of alcohol end groups at the chain ends.     

SYNTHESIS OF POLYMERS WITH PHOSPHONIUM END GROUPS BY ATOM TRANSFER RADICAL POLYMERIZATION

The end groups of polymers prepared by atom transfer radical polymerization (ATRP), are well-defined and determined by the initiator used, at least one of them is a halogen end group. The halogen end groups can be transformed to other functionalities such as phosphonium salts as demonstrated in this paper. Kinetic studies with the compounds 1-phenylethyl bromide and methyl 2-bromopropionate, models for the polystyrene and polyacrylate chain ends respectively, indicated that bromine end groups were readily transformed to phosphonium end groups upon the addition of phosphines. Stability tests with the obtained phosphonium salts showed that 1-phenylethyl trialkylphosphonium bromide was stable, even at higher temperatures and in the presence of free phosphines. The stability of the propionate analogue was limited due to the presence of the ester group in the molecule. Polystyrene and poly(methyl acrylate) phosphonium salts were synthesized and the presence of the end groups was demonstrated by ¹H NMR and ESI-MS or MALDI-TOFMS.     

POLYMERIZATION OF BUTYL METHACRYLATE BY IRON PYRIDINEBISIMINE COMPLEXES

Fe(Ⅱ)pyridinebisimine complexes activated with trialkylaluminium or modified methylaluminoxane(MMAO)ascatalysts were employed for the polymerization of butyl methacrylate(BMA).Polymer yields,catalytic activities andmolecular weights as well as molecular weight distributions of BMA can be controlled over a wide range by varying thereaction parameters such as cocatalyst,Al/Fe molar ratio,monomer/catalyst molar ratio,monomer concentration and reactiontemperature used in the polymerization.The catalytic activity of Fe(Ⅱ)complex was 11.1 kg_(polym)/mol_(Fe)h and the highestyield could reach 99.1% under optimum condition.