聚烷撑碳酸酯的研究现状

二氧化碳和环氧化物共聚可生成聚烷撑碳酸酯,而为实现利用二氧化碳的此一极好途径,还需从理论和实践上探明高度活化二氧化碳的方法。本文介绍了本领域的研究现状,包括反应的催化体系、反应机理、反应条件、聚烷撑碳酸酯的性质、改性方法和应用;还介绍了国内外科学家为催化剂效率而作的努力。     

戊二酸锌体系催化合成二氧化碳基聚碳酸酯研究进展

二氧化碳(CO2)是一种无毒无害、性质稳定、可再生的C1资源.近年来,以CO2为原料合成的CO2基聚酯受到了广泛关注.其中,戊二酸锌催化CO2和环氧化物共聚生成聚碳酸酯成为CO2高值转化的途径之一(特别是戊二酸锌催化CO2和环氧化物共聚,包括引入酸酐、环酯等三元共聚).我们综述了近年来戊二酸锌催化CO2基聚合反应的研究进展,对催化剂发展、结构、活性和产物性能等进行了系统的总结,分析了戊二酸锌催化剂在聚合反应过程中的优势和不足,最后对戊二酸锌催化剂的发展、挑战等进行了展望分析.     

有机小分子催化环醚与环状酸酐共聚研究进展

有机小分子催化聚合反应是合成化学领域新的研究方向。有机催化环醚(主要为环氧化物)与环状酸酐共聚制备聚酯的合成路线,由于单体具有来源广泛、有机催化剂低毒、对水和空气不敏感等特点,因而应用前景广阔。本文按有机小分子催化剂、环醚与环状酸酐的种类综述了近年来出现的有机催化共聚合成聚酯的反应,并详细讨论了该共聚反应及其机理,尤其是高催化活性和聚合可控性的Lewis酸碱对催化共聚的机理;提出了利用Lewis酸为增长链阴离子提供结构因素(如基团和电子结构效应)来调控聚合的方法。今后,催化环氧化物与环状酸酐共聚研究的中心任务仍然是发展新的高活性有机催化剂,并实现"活性"的全交替共聚反应,进一步提高共聚物的分子量,并实现共聚反应的化学选择性、区域和立体选择性的精确控制。     

金属有机骨架材料应用于二氧化碳环加成反应的研究进展

化石燃料的燃烧产生大量二氧化碳,引起了包括温室效应在内的诸多生态环境问题。二氧化碳作为一种重要的碳资源,也可用于制备多种重要的化工原料。环氧化合物与二氧化碳环加成是二氧化碳资源化利用的重要方向,并且产物环状碳酸酯在工业上能得到广泛利用。但二氧化碳具有惰性,不易被活化,因此寻求高效且稳定的催化剂成为实现二氧化碳快速转化的关键。金属有机骨架(MOFs)因具有不饱和金属位点、多孔性等优点而被应用到各类催化反应中。又因其具有路易斯酸碱位点,对二氧化碳与环氧化物环加成反应有着突出的催化效果,所以在该反应体系中也有着出色的表现,但其反应条件比较苛刻。环氧化物的活化是在环加成反应中的重要环节,卤化物对环氧化物的活化有很好的效果,但是存在难回收的问题;卤化物阴离子还会引起含铁金属的腐蚀,在一定程度上限制了大规模工业使用。很多研究人员致力于寻找减少使用该类助剂的方法,改进催化体系,于是催生出了关于MOFs改性的各类方法。本文列举了在催化二氧化碳与环氧化物环加成反应过程中关于MOFs的利用以及改性方法,并展望了MOFs材料在催化领域的发展前景。     

二氧化碳与环氧化物的共聚反应

自1969年Inoue用ZnEt₂/H₂O的混合物作催化剂由二氧化碳与环氧化物合成聚碳酸酯以来,化学家们在催化剂体系的设计与合成方面进行了大量研究。目前,这条合成聚碳酸酯的绿色合成路线已日渐成熟。本文综述了近5年来环氧化物与二氧化碳反应合成聚碳酸酯的研究成果,主要考察催化剂的催化活性对共聚反应的影响以及反应机理研究。     

二氧化碳与环氧化物共聚催化剂

综述了二氧化碳与环氧化物共聚催化剂方面的研究进展，重点介绍了90年代后期出现的新型高效率的高位阻型催化剂。     

二氧化碳硅氢化及相关转化的均相催化体系研究进展（英文）

利用二氧化碳作为C1原料进行硅氢化转化,是可持续性催化合成的重要方法之一.该方法能够将二氧化碳转化为不同氧化水平的高值化学品,例如甲酸、甲醛、甲醇和甲烷等.此外,胺可在特定的催化体系中与二氧化碳和硅烷多组分反应,实现基于二氧化碳硅氢化的N—H键酰基化和烷基化等转化.近年来,二氧化碳硅氢化领域的相关研究取得了显著的进展.综述了近三年来应用于二氧化碳硅氢化的主要均相催化体系的研究进展,介绍和总结催化剂的设计和相关催化性能,包括贵金属催化、廉价过渡金属催化、稀土金属催化、主族金属催化和无金属催化等催化体系,并讨论和展望了目前二氧化碳硅氢化的研究现状和潜在挑战.     

Fe—Al配位催化环氧丙烷均聚

用于环氧丙烷开环聚合的催化剂为有机金属化合物和稀土络合物等,在对于铁系催化剂催化丁二烯聚合、马来酸酐与苯乙烯共聚和邻苯二甲酸酐与环氧丙烷共聚的研究基础上,我们首次将这一类催化剂用于环氧化物的开环均聚上,发现Fe(acac)3-Al(i-Bu）3催化剂具有良好的催化活性,并进行了产物结构和反应动力学的研究,结构分析表明Fe(acac)3-Al(i-Bu）3催化剂体系具有良好的立体定向性。     

Fe-Al-α,α′-联吡啶催化体系催化马来酸酐与环氧丙烷开环共聚

马来酸酐与环氧丙烷开环共聚,所得聚酯具有功能团（C＝C）,可以通过接技、交联待方法改变其性能,马来酸杆与环氧化物开环共聚合成聚酯,所用催化剂通用有有机金属化合物和稀土 事物等,我们在铁系催化丁二聚合和马来酸酐与苯乙烯共聚的基础上,首次将Fe(acac)3-Al(i-Bu)3-α,α′－联吡啶催化剂用于马来酸酐与环氧化物开环共聚,发现该催化剂催化共聚反应具有时间短、收率高、共聚物交替度高等优点,并测定了共聚合反应动力学的参数。     

吡啶桥连双功能有机催化剂催化二氧化碳、环氧化物和芳香胺合成3-芳基-2-噁唑烷酮的研究

合成了一类羧基或羟基功能化的有机小分子催化剂,成功用于二氧化碳、环氧化物和芳香胺一锅法制备噁唑烷酮类化合物的制备.该催化体系具有反应条件温和、底物普适性好的优点.控制实验表明整个反应过程经过了三个阶段:环氧化物分别与二氧化碳、芳香胺反应形成环状碳酸酯、氨基醇,最终环状碳酸酯和氨基醇进一步反应形成噁唑烷酮类化合物.     

Alternating copolymerization of carbon dioxide and epoxide by manganese porphyrin: The first example of polycarbonate synthesis from 1-atm carbon dioxide

The first successful example of the formation of polycarbonate from 1-atm carbon dioxide and epoxide was demonstrated by the alternating copolymerization of carbon dioxide and epoxide with manganese porphyrin as a catalyst. The copolymerization of carbon dioxide and cyclohexene oxide with (porphinato)manganese acetate proceeded under the 1-atm pressure of carbon dioxide to give a copolymer with an alternating sequence. © 2003 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 41: 3549–3555, 2003     

Copolymerization of Carbon Dioxide and Epoxide: Functionality of the Copolymer

Carbon dioxide and epoxide copolymerize in the presence of some organometallic catalyst systems under moderate conditions to give aliphatic polycarbonates of high molecular weight. Some metalloporphyrins of aluminum and zinc were found to act as novel catalysts for the polymerization of epoxide and for the copolymerization of carbon dioxide and epoxide, though not alternating. The polymers are characterized by the narrow molecular weight distribution and the unusual stereoregularity. Starting from the copolymerization of carbon dioxide and trimethylsilyl glycidyl ether with diethylzinc-water catalyst system, a readily degradable polycarbonate having hydroxyl group was obtained.     

Mechanistic aspects of the copolymerization reaction of carbon dioxide and epoxides,using a chiral salen chromium chloride catalyst

The air-stable, chiral (salen)Cr(III)Cl complex (3), where H(2)salen = N,N'-bis(3,5-di-tert-butyl-salicylidene)-1,2-cyclohexene diamine, has been shown to be an effective catalyst for the coupling of cyclohexene oxide and carbon dioxide to afford poly(cyclohexenylene carbonate), along with a small quantity of its trans-cyclic carbonate. The thus produced polycarbonate contained >99% carbonate linkages and had a M(n) value of 8900 g/mol with a polydispersity index of 1.2 as determined by gel permeation chromatography. The turnover number (TON) and turnover frequency (TOF) values of 683 g of polym/g of Cr and 28.5 g of polym/g of Cr/h, respectively for reactions carried out at 80 degrees C and 58.5 bar pressure increased by over 3-fold upon addition of 5 equiv of the Lewis base cocatalyst, N-methyl imidazole. Although this chiral catalyst is well documented for the asymmetric ring-opening (ARO) of epoxides, in this instance the copolymer produced was completely atactic as illustrated by (13)C NMR spectroscopy. Whereas the mechanism for the (salen)Cr(III)-catalyzed ARO of epoxides displays a squared dependence on [catalyst], which presumably is true for the initiation step of the copolymerization reaction, the rate of carbonate chain growth leading to copolymer or cyclic carbonate formation is linearly dependent on [catalyst]. This was demonstrated herein by way of in situ measurements at 80 degrees C and 58.5 bar pressure. Hence, an alternative mechanism for copolymer production is operative, which is suggested to involve a concerted attack of epoxide at the axial site of the chromium(III) complex where the growing polymer chain for epoxide ring-opening resides. Preliminary investigations of this (salen)Cr(III)-catalyzed system for the coupling of propylene oxide and carbon dioxide reveal that although cyclic carbonate is the main product provided at elevated temperatures, at ambient temperature polycarbonate formation is dominant. A common reaction pathway for alicyclic (cyclohexene oxide) and aliphatic (propylene oxide) carbon dioxide coupling is thought to be in effect, where in the latter instance cyclic carbonate production has a greater temperature dependence compared to copolymer formation.     

Chemical Fixation of CO2 with Highly Efficient ZnCl/[BMIm]Br Catalyst System

The search for environmentally benign and economic process has been the impetus for much of the research involving epoxide and carbon dioxide coupling in view of the so called "green chemistry" and" atom economy ", since CO2 is a renewable resource and can be used as a safe and cheap C 1 building block to synthesize useful organic compounds without producing any coproducts.[1-2] One of the most attractive synthetic goals starting from carbon dioxide is the chemical fixation of CO2 onto epoxide to afford the five-membered cyclic carbonates (Scheme 1),which are excellent aprotic polar solvents and are used extensively as intermediates in the production of pharmaceuticals and fine chemicals.[3] In the last decades of the twentieth century numerous catalytic systems have been developed for this transformation. While some advances have been obtained, all suffer from either low catalyst stability/reactivity, the need for co-solvent, or the requirement for high pressure and/or catalyst costing expensive.[4] Therefore, to find an effective,not exrensive, environmentally benign and economic catalyst system is urgent.In this paper, chemical fixation of CO2 with mono-substituted terminal epoxides or cyclohexene oxide to form cyclic carbonates under the ZnCl2/[BMIm]Br Catalyst System without using additional organic solvents was achieved in excellent selectivity (＞98%) and TOF(5410h-1) Besides,the pure cis-cyclic carbonate of cyclohexene oxide was obtained in this catalyst system.It was important to note that the catalyst could be recovered by simple vacuum distillation of the corresponding cyclic carbonates and could be used six times almost without losing its catalytic activity and selectivity. The catalyst system was found to be applicable to a variety of terminal epoxides and cyclohexene oxide, forming the corresponding cyclic carbonates in very high TOF and more than 98% selectivity. Based on the obtained results, we also propose the plausible mechanism for this chemical fixation reaction of CO2.     

聚(1,2-亚丙基碳酸酯)的应用研究新进展

二氧化碳共聚物;环氧丙烷;聚(1;2-亚丙基碳酸酯)的应用研究新进展;脂肪族聚碳酸酯     

Development in the green synthesis of cyclic carbonate from carbon dioxide using ionic liquids

This brief review presents the recent development in the synthesis of cyclic carbonate from carbon dioxide (CO₂) using ionic liquids as catalyst and/or reaction medium. The synthesis of cyclic carbonate includes three aspects: catalytic reaction of CO₂ and epoxide, electrochemical reaction of CO₂ and epoxide, and oxidative carboxylation of olefin. Some ionic liquids are suitable catalysts and/or solvents to the CO₂ fixation to produce cyclic carbonate. The activity of ionic liquid is greatly enhanced by the addition of Lewis acidic compounds of metal halides or metal complexes that have no or low activity by themselves. Using ionic liquids for the electrochemical synthesis of the cyclic carbonate can avoid harmful organic solvents, supporting electrolytes and catalysts, which are necessary for conventional electrochemical reaction systems. Although the ionic liquid is better for the oxidative carboxylation of olefin than the ordinary catalysts reported previously, this reaction system is at a preliminary stage. Using the ionic liquids, the synthesis process will become greener and simpler because of easy product separation and catalyst recycling and unnecessary use of volatile and harmful organic solvents.     

The copolymerization of carbon dioxide and [2-(3,4-epoxycyclohexyl)ethyl]trimethoxysilane catalyzed by (salen)CrCl. Formation of a CO2 soluble polycarbonate

The copolymerization of 2-(3,4-epoxycyclohexyl)ethyl-trimethoxysilane and carbon dioxide catalyzed by (salen)Cr(III)Cl (H(2)salen = N,N'-bis(3,5-di-tert-butylsalicylidene)-1,2-ethylenediimine) with 2.5 equiv of N-MeIm as cocatalyst affords a polycarbonate devoid of polyether linkages, along with only a trace quantity of cyclic carbonate. The presence of the trimethoxysilane functionality in the epoxide not only provided the reactant monomer and product copolymer high solubility in liquid carbon dioxide but also provided the ability to cross-link the copolymer and thereby greatly alter the physical properties of the thus formed polycarbonate. In addition, the enhanced solubility of the copolymer in liquid CO(2) furnishes a ready means of removing the highly colored metal catalyst from the polycarbonate product.     

可降解的CO2基共聚物的研究进展

随着社会的发展,二氧化碳的排放量逐年增加,大量二氧化碳进入大气层,一方面加剧了温室效应,另一方面浪费了碳资源.人们研究捕捉、固定二氧化碳的技术,希望减少二氧化碳的排放并充分利用这一潜在的＂碳源＂.进行化学反应是利用二氧化碳的一种方法[1-2].二氧化碳化学性质稳定,通常与活性高的物质才能反应.1969年,日本井上祥平教授[3]开     

Nano-sized polydopamine-based biomimetic catalyst for the efficient synthesis of cyclic carbonates

Polydopamine (PDA) is a biocompatible and biomimetic material. Herein, nano-sized PDA sphere was prepared and the combination of alkali metal halide and PDA was investigated as a catalyst for the synthesis of cyclic carbonates from epoxide and carbon dioxide. It was found that the activity of PDA could be obviously enhanced in the presence of alkali metal salts. After reaction, the catalyst and the products could be separated easily, and the catalyst was reusable. The origin of the high catalytic efficiency and the reaction mechanism were also discussed.