新型含硼聚芳醚酮的制备、性能及在偶氮聚芳醚酮合成中的应用

利用双酚A型聚芳醚酮与联硼酸频哪醇酯在[Ir(COD)Cl]2和4,4'-二叔丁基-2,2'-联吡啶催化下反应,制备了新型含硼酸酯双酚A型聚芳醚酮,通过控制联硼酸频哪醇酯的投入量来实现硼酸酯的定量引入.再经过高碘酸钠作用得到含硼酸双酚A型聚芳醚酮,最后,通过高效Suzuki-Miyaura反应将偶氮定量引入到聚芳醚酮主链.利用核磁共振(1H NMR)确定了聚合物的结构,利用凝胶渗透色谱(GPC)确定了聚合物的分子量,利用差示扫描量热分析(DSC)和热失重分析(TGA)研究了聚合物的热性能,利用紫外-可见光谱(UVVis)研究了偶氮聚芳醚酮的光谱学性能.     

具有温敏特性的光学活性嵌段聚合物Click合成与表征

以末端含有炔基的2-十二烷基三硫代碳酸酯-2-甲基-丙酸丙炔醇酯(DMPE)为链转移剂(CTA),2,2′偶氮二异丁腈(AIBN)为引发剂,在N,N-二甲基甲酰胺(DMF)中,利用可逆加成-断裂链转移(RAFT)聚合反应制备了分子链末端带炔基的均聚物聚(N-丙烯酰基-L-缬氨酰甲胺)(PAVMA—C帒CH),然后与叠氮基封端的聚乙二醇单甲醚(MPEG-N3)进行"click"偶合反应,制备具有温敏特性的光学活性嵌段聚合物MPEG-b-PAVMA.利用1H-NMR和体积排阻色谱(SEC)等表征了所合成的均聚物和共聚物的结构和分子量分布.1H-NMR结果表明所合成的嵌段共聚物中MPEG和PAVMA链段的重复单元数分别为115和55.利用紫外分光光度计测试了均聚物及嵌段聚合物的温敏特性,结果表明均聚物和共聚物在水中的低临界溶解温度(LCST)分别为6.5℃和19.5℃.比旋光度测试结果表明,均聚物和共聚物具有旋光性,同时相比于单体,其旋光能力有所降低.圆二色谱法(CD)的测试结果显示,均聚物和嵌段共聚物在220nm和197nm附近分别有一个较弱的正Cotton效应峰和一个较强的负Cotton效应峰,并且在水溶液中主要以无规的二级构象结构存在。     

高密度柱状聚合物刷的合成

通过铜催化的叠氮-炔偶联反应(CuAAC),利用grafting-onto方法合成每个主链重复单元带有多于一条侧链的高接枝密度的柱状聚合物刷.首先,合成了带有缩酮保护的甲基丙烯酸2,2-双羟甲基丙酯单体(bisMPMA),并通过可逆加成-断裂链转移(RAFT)聚合得到窄分子量分布的线形聚合物.在酸性条件下脱去缩酮保护后,以羟基与戊炔酸酐的酯化反应,得到了每个重复单元带有2个炔基的聚合物主链.之后,利用高效的CuAAC反应,将末端带有叠氮基团的聚环氧乙烷(PEO)或聚苯乙烯(PS)侧链接枝到主链上,用核磁共振氢谱(1H-NMR)和体积排阻色谱(SEC)等对聚合物刷的结构进行表征.     

锌-钴双金属氰化络合物催化二硫化碳与氧化环己烯共聚研究

报道了锌-钴双金属氰化络合物(double metal cyanide complex,DMCC)催化CS2与氧化环己烯(CHO)直接共聚生成脂环族聚硫代碳酸酯的反应.傅立叶红外光谱(FTIR)及拉曼(Raman)光谱结果表明该共聚物端基为-OH和-SH结构;核磁共振(1H和13C-NMR)结果表明共聚物主链含碳酸酯-O(CO)O-链节和4种硫代碳酸酯-O(CO)S-、-S(CO)S-、-O(CS)S-和-S(CS)S-链节结构;气相色谱-质谱(GC-MS)联用结果表明产物中含有环硫环己烷及3种环状硫代碳酸酯.聚合物链结构和产物种类表明CS2/CHO共聚反应存在氧-硫原子交换反应过程.     

一种新型的交联极化聚合物的合成及性能研究

以成膜性能优异、主链上含有多个羟基的聚双酚A二缩水甘油醚-苯胺(BPAN)为骨架,将二阶非线性光学活性发色团分子以键合形式挂接到聚合物主链上,形成新型侧链型聚合物.此聚合物保留了原聚合物体系成膜性好和可进一步交联等优点.极化过程中以含有异氰酸酯基的同种发色团分子作为交联剂,得到发色团含量进一步提高的交联型极化聚合物.采用衰减全反射法(ATR)测得体系的电光系数(r₃₃)为6.7 pm/V(1315 nm).     

立构复合PL(D) LA-TMC无规共聚物的制备、结构与性能

以辛酸亚锡为催化剂,通过开环聚合法制备了聚左旋乳酸-三亚甲基碳酸酯(PLLA-TMC)和聚右旋乳酸-三亚甲基碳酸酯(PDLA-TMC)无规共聚物.利用共聚物中PLLA/PDLA链段形成立构复合体,通过溶液浇注法制备了PLLA-TMC/PDLA-TMC立构复合聚乳酸材料(sc-PLA-TMC).研究结果表明,聚合物链中的柔性TMC单元可以增强L(D)LA链段的运动能力,有助于不同旋光性的LA链段形成立构复合晶体,但也使得L(D)LA链段的规整度和序列长度降低.即随着共聚物链段中柔性TMC单元摩尔含量的增加,sc-PLA-TMC中同质结晶能力降低.当TMC含量≥5%时,仅生成熔点200℃的PLLA/PDLA立构复合结晶,表明sc-PLA-TMC的耐热性有所提高.蛋白酶K降解实验表明,PL(D)LA-TMC共聚物的降解速率不但比PLLA高,而且可通过共聚物中TMC含量进行调控.     

聚碳酸酯基固态聚合物电解质的研究进展

液态锂离子电池由于采用易泄露、易挥发、易燃烧的碳酸酯有机溶剂,在高温或极端条件下使用时,存在极大的安全隐患.使用固态电解质替代液态电解液,可以从根本上避免此类安全问题的发生,与此同时还可以大幅度提升固态锂电池的能量密度.固态电解质又分为无机固态电解质和聚合物固态电解质2大类.无机固态电解质能够在宽的温度范围内保持化学稳定性,并且电化学窗口较宽,机械强度更高,室温离子电导率较高,但脆性较大,柔韧性差,制备工艺复杂,成本较高.聚合物固态电解质,室温离子电导率偏低,难以满足室温锂离子电池的应用,但其加工成型容易,形状可变.比较而言,固态聚合物电解质,更适宜大规模生产,离产业化相对更近.固态聚合物电解质中研究较多的是聚醚基固态聚合物电解质(如聚环氧乙烷和聚环氧丙烷),但其缺点是室温离子电导率低,需要对其改性或进一步开发综合性能更加优异的其他固态聚合物电解质.聚碳酸酯基固态聚合物电解质由于其特殊的分子结构(含有强极性碳酸酯基团)以及高介电常数,可以有效减弱阴阳离子间的相互作用,提高载流子数量,从而提高离子电导率,因此被认为是一类非常有前途的固态聚合物电解质体系.基于此,本文重点综述了最近研究热点的聚碳酸酯基固态聚合物电解质,包括聚(三亚甲基碳酸酯)体系、聚(碳酸丙烯酯)体系、聚(碳酸乙烯酯)体系和聚(碳酸亚乙烯酯)体系等,并详细阐述了上述每种聚碳酸酯基固态聚合物电解质的制备、电化学性能、优缺点及改性手段,归纳出其离子配位-解配位过程和离子扩散机制,还对聚碳酸酯基固态聚合物电解质的未来发展方向和研究趋势望进行了预测和展望.     

二氧化碳三元共聚物催化合成的研究进展

讨论在聚甲基乙撑碳酸酯（PPC）主链中引入第三单体改善聚合物的性能,并对引入不同第三单体的反应机理、结构、性能以及应用进行讨论。     

利用β-环糊精提高聚碳酸1,2-丙二酯的热稳定性

将聚碳酸1,2-丙二酯与β-环糊精在60℃下固相共混,得到了两者的内含复合物.线性的聚碳酸1,2-丙二酯穿入β-环糊精分子空腔形成准聚轮烷结构,导致聚合物分子链的刚性增大,主链上受热易发生断裂的碳酸酯键由于受到环糊精空腔的保护变得稳定,聚碳酸1,2-丙二酯的热稳定性得到提高.实验结果表明,所得内含复合物的玻璃化转变温度(T_g)提高了5℃,在N_2氛围下10%热失重温度(T_(d-10%))增加了33℃.     

含偶氮苯侧链分子刷聚合物的合成及其光响应自组装

分子刷聚合物伸展的高分子主链、高密度的侧链和较低的侧链空间缠结,使其展现出独特的流变学、力学性能和特殊的分子聚集状态,在纳米技术、表面科学等领域有着广泛的应用前景.基于同时含有2-羰基溴与炔基基团的大分子试剂聚2-((2-溴代丙酰氧基)甲基)丙烯酸丙炔酯,引发偶氮苯丙烯酸酯单体的原子转移自由基聚合(ATRP)与叠氮功能化的巴比妥酸衍生物的点击反应,合成了新型含偶氮苯侧链的分子刷聚合物聚丙烯酸酯-g-聚(6-(4-丁基-4′-氧偶氮苯)正己基丙烯酸酯)/巴比妥酸(PA-g-PAzo/Bar),研究了其在溶液中的自组装和光响应性行为.随着分子刷聚合物浓度的增加,聚集体由柱状胶束向复合胶束转变.由于光响应性偶氮苯侧链的存在,在紫外光的照射下偶氮苯生色团发生trans-cis异构化转变,促使柱状胶束融合形成多孔网状聚集体,同时球形复合胶束融合形成珍珠项链状聚集体.     

Synthesis of polycarbonate from dimethyl carbonate and bisphenol-a through a non-phosgene process

A novel nonphosgene process for producing bisphenol-A polycarbonate (PC) was developed through a transesterification between bisphenol-A (BPA) and dimethyl carbonate (DMC) and a melt-polycondensation of the resulting bisphenol-A bismethylcarbonate (1). The transesterification was carried out by heating bisphenol A in dimethylcarbonate in the presence of Lewis acid catalysts, removing the by-producing methanol using molecular shieves 4A. Among various catalysts, a combination of (Bu₂SnCl)₂O and dimethylaminopyridine gave the best results to produce 1 in 22% yield for 48 h. Using a larger amount of the molecular sieves further improved the yield to 80% in 120 h. The resulting 1 was heated under reduced pressure in the presence of titanium catalysts to produce PC in good yields. The resulting PC had high weight average molecular weight (M_w) of 75,000. © 1999 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 37: 2087–2093, 1999     

Tuning the optical clarity of glass fiber‐reinforced polycarbonates by reactive blending with alternatives from biorenewable isosorbide

Optically transparent and mechanically strong glass fiber (GF)‐reinforced polycarbonate (PC) composites were fabricated via reacting with biorenewable isosorbide (ISB) moiety. While direct copolymerization of ISB and bisphenol A (BPA) by melt transesterification with diphenyl carbonate remained difficult due to the large discrepancy of reactivity and low thermal stability of ISB, we demonstrated in this work that ISB and BPA copolycarbonates with high molecular weight, low discoloration, and excellent optical transparency can be fabricated at 250 °C within 2.5 min by reactive blending of commercially available ISB‐based PC and BPA‐PC. A systematic study of synthesis, thermal degradation, and reactive blending of ISB‐containing PCs was performed to distinguish the reactivity between ISB and BPA, elucidate the effect of catalyst on chain scission, and testify the reaction mechanism of the unexpected asymmetrical inner–inner carbonate exchange. We clarified that the hydroxyl group on BPA exhibited a low reactivity and Lewis acid‐catalytic transesterification played a key role in preventing from the chain scission during the asymmetrical inner–inner exchange. Another unexpected factor that effectively suppressed the further chain scission was the miscibility of the ISB‐based PC with BPA‐PC once each chain on average was carbonate exchanged with its counterpart to form a “biblock” PC. © 2019 Wiley Periodicals, Inc. J. Polym. Sci., Part A: Polym. Chem. 2019, 57, 1670–1681     

Anionic bulk oligomerization of ethylene and propylene carbonate initiated by bisphenol‐A/base systems

When the bulk oligomerization of 1,3‐dioxolan‐2‐one (ethylene carbonate, EC) and 4‐methyl‐1,3‐dioxolan‐2‐one (propylene carbonate, PC) with the 2,2‐bis(4‐hydroxyphenyl)propane (bisphenol‐A, BPA)/base system (bases such as KHCO₃, K₂CO₃, KOH, Li₂CO₃, and t‐BuOK) was investigated at elevated temperature, significant differences were observed. Oligomerization of EC initiated by BPA/base readily takes place, but the oligomerization of PC is inhibited. The very first propylene carbonate/propylene oxide unit readily forms a phenolic ether bond with the functional groups of BPA phenolate, but the addition of the second monomer unit is rather slow. The oligomerization of EC yields symmetrical oligo(ethylene oxide) side chains. According to IR studies the oligomeric chains formed from PC with BPA contain not only ether but also carbonate bonds. The in situ step oligomerization of the BPA dipropoxylate was also identified by SEC, and a possible reaction mechanism is proposed. © 1999 John Wiley & Sons, Inc. J Polym Sci A: Polym Chem 37: 545–550, 1999     

NaOH与TEAH催化熔融酯交换合成聚碳酸酯及其重排产物研究

分别以NaOH和氢氧化四乙基铵(TEAH)为催化剂,碳酸二苯酯(DPC)和双酚A(BPA)为原料,采用熔融酯交换法合成聚碳酸酯.当DPC与BPA的摩尔比为1.05∶1,催化剂与BPA的摩尔比为5×10-4∶1时,在所采用的工艺条件下,可分别得到Mn、Mw/Mn为1.69×104、1.97(NaOH催化),1.23 × ...     

聚碳酸酯在亚临界水中解聚的研究

采用间歇式高压反应装置研究聚碳酸酯(PC)在亚临界水中的解聚.在温度260～340℃、压力4.8～14.8 MPa、反应时间5～60min的反应条件下,考察了反应温度及反应时间对PC解聚率及主产物双酚A(BPA)和苯酚(PhOH)回收率的影响.产物分别采用傅里叶红外光谱(FTIR)、扫描电子显微镜(SEM)、气质联谱(...     

Depolymerization of Poly（bisphenol A carbonate） in Subcritical and Supercritical Toluene

The depolymerization of poly(bisphenol A carbonate)(PC) in subcritical and supercritical toluene was studied. The experimental parameters, which influence the depolymerization reaction such as temperature (570-633 K), pressure (4.0-7.0 MPa), reaction time (5-60 min), and toluene to PC weight ratio (3.0-11.0), were investigated, and the reaction products were determined by GC, GC/MS and FT-IR spectrometer. It was found that the main product of the depolymerization reaction was bisphenol A(BPA). BPA accounted for over 55.7% of the depolymerization products at reaction temperature 613 K, pressure 5.0-6.0 MPa, reaction time 15 min and toluene/PC weight ratio of around 7.0.     

不同链结构的双酚A聚碳酸酯对脂肪族聚碳酸酯结晶行为的影响

脂肪族聚碳酸酯(APC)是一类可降解的高分子材料,因其生产工艺可固定温室气体的主要成分二氧化碳,这种可降解塑料得到了越来越多的关注.作为半结晶高分子材料,脂肪族聚碳酸酯的结晶性能和结晶结构对成型加工、力学性能和降解性能具有重要的影响.借助热分析(示差扫描量热仪DSC)和形态学观察(偏光显微镜POM)两种方法研究了不同链结构的双酚A型聚碳酸酯对半结晶脂肪族聚碳酸酯——聚碳酸1,4-丁二醇酯结晶动力学行为的影响.实验发现质量分数1%的双酚A聚碳酸酯的加入促进了聚碳酸1,4-丁二醇酯的成核,但不同链结构的双酚A聚碳酸酯对其晶体生长具有相反的作用,线形双酚A聚碳酸酯(PC-L)能够促进晶体生长,而支化双酚A聚碳酸酯(PC-B)则抑制晶体生长.用原子力显微镜在轻敲模式下研究了两种双酚A聚碳酸酯与APC共混物熔融状态下的相结构,发现熔体结构的不同是导致两种共混物与纯的APC相比,结晶速率呈现相反变化趋势的主要原因.     

TRANSESTERIFICATION OF POLY（BISPHENOL A CARBONATE） WITH AROMATIC AND ALIPHATIC SEGMENTS IN BUTYLENE TEREPHTHALATE-CAPROLACTONE COPOLYESTER

In this article, the transesterification of poly(bisphenol A carbonate) (PC) with butylene terephthalate-caprolactone copolyester at a weight ratio 50/50 (BCL(21)) was thoroughly investigated by proton nuclear magnetic resonance spectroscopy (^1H-NMR), in conjunction with a model compound. The ^1H-NMR results of the annealed blend PC/BCL(21) show that the formation of bisphenol A-terephthalate ester units is the same as in the annealed blend of PC with PBT, and the transesterification actually occurs between PC and butylene terephthalate (BT) segments in BCL(21). By comparison with the model compound bisphenol A dibutyrate, the new signal appearing at δ=2.56 in the ^1H-NMR spectrum confirms the existence of bisphenol A caprolactone ester units resulting from the exchange reaction of PC with caprolactone (CL) segments. ^1H-NMR analysis of the transesterification rates reveals that the reaction of PC with aromatic and aliphatic segments in BCL(21) proceeds in a random manner. The miscibility of the blend PC/BCL(21) copolyester is favorable for the transesterification of PC with BT segments and CL segments.     

Mechanistic aspects of ester–carbonate exchange in polycarbonate/cycloaliphatic polyester with model reactions

The reactive blending of bisphenol A polycarbonate (PC) with poly(1,4‐cyclohexanedimethylene‐1,4‐cyclohexanedicarboxylate) (PCCD) was investigated with a new high‐temperature solution‐blending methodology. The ester–carbonate exchange reaction (transesterification) in the blends was studied with NMR and Fourier transform infrared. The composition analysis of the PC/PCCD blends was performed with ¹H NMR, and the molecular weights were determined with viscosity methods. 1,4‐Dimethylcyclohexanedicarboxylate, 1,4‐cyclohexanedicarboxylic acid, and 1,4‐cyclohexanedimethanol were reacted with PC to study the tendency of polyester chain‐end reactions such as transesterification, acidolysis, and alcoholysis. These model reactions revealed that the reactive blending was affected by both alcoholysis and transesterification, whereas acidolysis was absent. The model reaction products were used to study the mechanistic aspects of PC/PCCD reactive blending, which indicated the formation of three stable triads; two corresponded to symmetrical and unsymmetrical aromatic–cycloaliphatic esters, and the other corresponded to aromatic–cycloaliphatic ethers. The composition analysis confirmed that in PC/PCCD reactive blending, the exchange reaction predominantly occurred in the polymer main chains, and the influence of the end groups was insignificant. The effect of the catalyst concentration and PC/PCCD composition on the extent of the exchange reaction was also investigated. Thermal analysis by differential scanning calorimetry revealed that the ester–carbonate exchange enhanced the compatibilization of PC/PCCD, and a single glass‐transition temperature was observed for the miscible blends. © 2004 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 42: 3996–4008, 2004     

氧化羰化法直接合成双酚A型聚碳酸酯

使用Pd系氧化还原催化体系氧化羰化双酚A和CO直接合成了聚碳酸酯。在PdCl20．016mmol,n(Pd)：n(Cu)：n(对苯醌)：n(四丁基溴化铵)=1：4：40：40,双酚A22mmol,CH2Cl250mL。4A分子筛4g,CO5．5MPa,O2O．5MPa,反应温度100℃,搅拌速度800rpm的条件下反应12h,得到的聚碳酸酯重均分子量M。为2450。探索了杂多酸和杂多酸的四丁基铵盐对氧化羰化双酚A直接合成聚碳酸酯的促进作用。使用Pd-Mn-(TBA)8SiW12O42啦催化剂体系,在上述相同的实验条件下反应8h,得到的聚碳酸酯重均分子量Mw为2225,好于Pd-Cu-苯醌催化体系的结果(Mw=1720)。对合成得到的聚碳酸酯进行了IR光谱分析,并通过与相同条件下得到的商品聚碳酸酯(Mw=22000)的IR光谱对照,对实验结果进行了确认。