聚乙二醇功能化离子液体的制备及其在有机反应中的应用

聚乙二醇功能化离子液体作为一个新的研究方向受到了化学研究者关注,该类离子液体已经成功地应用于许多有机合成反应中,可以明显改善催化剂性能,并可在一定程度上解决传统催化剂使用中遇到的难分离、难回收再利用的问题。本文介绍了聚乙二醇功能化离子液体的发展历程、制备方法和其作为反应介质、溶剂或催化剂在有机合成反应中应用的最新研究成果,主要包括加成反应、缩合反应、还原反应、酯化反应、硝化反应、氧化反应、水解反应、Heck 反应以及Suzuki-Miyaura反应等。     

基于功能离子液体促进的有机反应研究进展

离子液体作为绿色溶剂和催化剂,具有低挥发性,优良的热稳定性、溶解性以及可回收等优点,近年来广泛应用于有机合成领域中,在提高反应速率,反应选择性等方面发挥了巨大作用.综述了离子液体作为催化剂或溶剂在传统有机合成反应中的最新研究成果,包括Baylis-Hillman反应、Michael加成反应、氧化还原反应、Knoevenagel缩合反应、Aldol缩合反应、Diels-Alder反应、Heck偶联反应、Suzuki反应、不对称反应、Biginelli反应、Mannich反应、Hantzsch多组分反应.分析离子液体结构对反应催化性能的影响,探讨其反应机理,为开发新型结构可调性功能离子液体打下基础.     

碱性离子液体在有机合成中的应用研究进展

介绍了碱性离子液体特点及其分类,综述了近年来碱性离子液体作为催化剂和反应介质在有机合成反应的最新研究成果.主要包括:Michael加成、Mannich反应、Knoevenagel缩合、Markovnikov加成、Henry反应、Perkin反应、Heck偶联反应、烷基化、羰基化反应和"中断性"Feist-Benary反应.     

微波促进离子液体相反应在有机合成中的应用

微波促进离子液体相有机合成技术作为一种新型的绿色化学合成法,引起了人们极大的兴趣。在离子液体中,微波辅助下反应快速、收率高、选择性好、后处理简单,离子液体经简单再生后可多次套用。本文综述了以离子液体为反应介质或催化剂的微波辅助技术在多种类型有机反应中的研究成果,主要包括了环合反应、亲核取代反应、金属复分解反应、酰化反应、重排反应、聚合反应、偶联反应、氧化还原反应和选择性脱溴反应等。     

离子液体作为微波吸收剂促进苯甲醛与巴比妥酸的缩合反应

离子液体是纯粹由离子组成的液体,通常由二烷基季铵阳离子与四氟硼酸根、六氟磷酸根、卤素负离子等阴离子组成.离子液体具有强极性、低蒸汽压,对无机和有机物具有良好的溶解性以及对绝大部分试剂稳定等一系列特殊性质,常作为反应介质或催化剂用于有机合成中[1,2].     

离子液体中的串联有机合成反应

近年来迅速发展起来的串联反应为解决传统的有机合成反应提供了有效的途径. 将离子液体应用于串联反应, 反应不仅具有串联反应的优点, 如反应条件温和, 目标产物的选择性好、产率高, 中间体无需分离, 操作简单等, 还具有离子液体的诸多优点: 离子液体/催化剂可循环使用, 产品容易分离、纯度高等.     

碱性离子液体催化的Claisen-Schmidt缩合反应

合成了6种以N-甲基咪唑为基体的碱性离子液体, 以其作为催化剂, 在无溶剂条件下, 成功催化了Claisen-Schmidt缩合反应. 采用Hammett指示剂法对碱性离子液体的碱性强度和碱量进行表征. 实验结果表明, 此系列碱性离子液体对Claisen-Schmidt缩合反应具有较高的催化活性, 反应条件温和, 产物产率较高, 离子液体经简单处理后可多次循环使用, 催化活性未见明显降低.     

Br(o)nsted酸性离子液体催化异丁醛和叔丁醇缩合反应

考察了Br(o)nsted酸性离子液体同时作为溶剂和催化剂催化异丁醛和叔丁醇缩合制备 2,5-二甲基-2,4-己二烯的反应性能.结果表明,Br(o)nsted酸性离子液体具有良好的催化性能,反应后反应产物与离子液体自动分层易分离,离子液体经过真空干燥处理后可以作为溶剂和催化剂循环使用.调变离子液体中的阳离子或阴离子的结构对催化性能有较大的影响.     

Brnsted酸性离子液体催化异丁醛和叔丁醇缩合反应

考察了Brnsted酸性离子液体同时作为溶剂和催化剂催化异丁醛和叔丁醇缩合制备2,5-二甲基-2,4-己二烯的反应性能.结果表明,Brnsted酸性离子液体具有良好的催化性能,反应后反应产物与离子液体自动分层易分离,离子液体经过真空干燥处理后可以作为溶剂和催化剂循环使用.调变离子液体中的阳离子或阴离子的结构对催化性能有较大的影响.     

功能化离子液体在Knoevenagel缩合中的研究进展

离子液体具备熔点低、不可燃性、热稳定性好、溶解性好、可设计性及可重复利用性等一系列优点,因此常以催化剂、溶剂的形式应用于有机合成领域中.从离子液体阳离子电荷中心所在位置的不同出发,分别介绍了近年来非环类、环类及负载型功能化离子液体在Knoevenagel缩合反应中的应用进展,并对功能化离子液体的结构特点、催化活性及某些催化剂可能的催化机理等方面展开了论述.     

Ionic liquid assisted synthesis of S-heterocycles

Some organic solvents are highly toxic, flammable, and even explosive. In particular, high vapor pressures and toxicity of certain volatile organic solvents may cause significant environmental problems. Therefore, alternative solvents or media with tunable and versatile solvation properties for conducting chemical reactions and materials synthesis have been actively sought. Ionic liquids have numerous applications not only as environmentally benign reaction media, but also as catalysts and reagents. Due to the increase of environmental consciousness in chemical research and industry, the challenge for a sustainable environment calls for clean procedures that avoid the use of harmful organic solvents. Due to the special properties of ILs (ionic liquids) such as wide liquid range, good solvating ability, negligible vapor pressure, non-inflammability, non-volatility, environment friendly medium, high thermal stability, good stability in air and moisture, easy recycling and rate promoters etc. they are used in organic synthesis. Therefore, ionic liquids have attracted the attention of chemists and act as catalyst and reaction medium in organic reactions with high activity. Highly efficient methods are explored for the preparation of S-heterocycles with the application of ILs as catalyst and reaction medium.     

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.     

Novel Brønsted acidic ionic liquids and their use as dual solvent-catalysts

The reaction of triphenylphosphine or N-butylimidazole with cyclic sultones gives zwitterions that are subsequently converted into ionic liquids by reaction with trifluoromethane sulfonic acid or p-toluenesulfonic acid. The resulting ionic liquids have cations to which are tethered alkane sulfonic acid groups. These Br?nsted acidic ionic liquids are useful solvent/catalysts for several organic reactions, including Fischer esterification, alcohol dehydrodimerization and the pinacol rearrangement. The new ionic liquids combine the low volatility and ease of separation from product normally associated with solid acid catalysts, with the higher activity and yields normally found using conventional liquid acids.     

Basic ionic liquids. A short review

Basic ionic liquids as environmental-friendly solvents and catalysts with high activity and selectivity and easily recovered materials were used to replace traditional bases such as KOH, NaOH, K₂CO₃, NaHCO₃, NaOAc, triethylamine, or tetrabutylammonium acetate. Using the traditional bases generally suffered from disadvantages such as waste production, corrosion and environmental problems. Basic ionic liquids offering a new possibility for developing environmentally friendly basic catalysts due to the combination of the advantages of inorganic bases and ionic liquids. They are flexible, nonvolatile,noncorrosive, and immiscible with many organic solvents. Basic ionic liquids (BILs) have been used in base-catalyzed processes such as Michael addition, Markovnikov addition, Knoevenagel condensation, Henry reaction, Mannich reaction, oximation, Feist-Benary reaction and etc. In this short review, we wish to present an overview of the types, properties, synthesis and applications of basic ionic liquids.     

短孔道介孔分子筛Zr-Ce-SBA-15固载酸性离子液体催化合成双酚F

通过化学键接的方式,将酸性离子液体(ILs)分别负载于两种不同的硅基载体上,成功制备了SBA-15-ILs(SILs)与Zr-Ce-SBA-15-ILs(ZCSILs)等两种固载化酸性离子液体。 通过傅里叶变换红外光谱仪(FT-IR)、热重分析仪(TG-DTG)、X射线衍射仪(XRD)、N₂吸附-脱附比表面仪(BET)、透射电子显微镜(TEM)、扫描电子显微镜(SEM)与有机元素分析仪(OEA)等对所制备催化剂的物化性能进行了表征,并进一步研究了其在甲醛-苯酚合成二羟基二苯基甲烷(双酚F,BPF)中的催化活性。 结果表明:短孔道的ZCSILs具有较高比表面积、较多的离子液体负载量和相对优异的催化活性。 当m(催化剂)/m(甲醛)=0.36,n(苯酚)/n(甲醛)=30,反应时间90 min、反应温度90 ℃时,BPF收率可达95.6%,对4,4′-BPF的选择性达到44.8%,且所制备的ZCSILs重复使用5次后,依然显示优异的催化活性。     

离子液体在自由基聚合反应中的应用研究进展

室温离子液体是完全由离子构成的液体,具有几乎没有蒸汽压、溶解度大、溶解范围广、易于回收利用、稳定性好等特点,广泛应用于电化学、有机反应、分离萃取、复合材料等各个领域。近年来已成为各种聚合反应研究的重要课题,且主要集中于自由基聚合反应。作为聚合反应的溶剂,离子液体对聚合反应速率、分子量、聚合物的结构性能都有一定影响。本文根据近几年的文献,归纳分析了离子液体中的常规自由基聚合和活性自由基聚合的反应动力学、反应机理、聚合产物的结构和性能以及离子液体的回收利用等问题。     

Charge-tagged polar phosphine ligands in Pd-catalysed reactions in aqueous and ionic media

A new range of polar imidazolium and phosphate-containing ligands was synthesised from readily available starting materials in high yielding multi-step transformations. These ligands were used to generate Pd catalysts for Suzuki and Heck C–C coupling reactions in organic and organic/aqueous media. The catalysts performed well in aqueous media in the Suzuki reaction and less well in the Heck reaction, related to substrate solubility in the aqueous media. When moving to ionic liquids, the Heck reaction dramatically improved, especially in media compatible with the polar catalysts and the non-polar reagents. In all cases, the catalysts were stable to the formation of Pd black, a form of degradation that frequently befalls Pd catalysts. The catalysts could be successfully recycled without loss of activity.     

碱性离子液体催化甘油合成1,2-甘油碳酸酯(英)

以离子液体为催化剂,在无溶剂体系中,考察了生物质平台化合物甘油转化1,2-甘油碳酸酯的反应.与酸性离子液体和常用无机碱性催化剂相比,碱性离子液体咪唑基1-丁基-3-甲基咪唑([Bmim]Im)、氢氧化1-丁基-3-甲基咪唑([Bmim]OH)、咪唑基1-烯丙基-3-甲基咪唑([Amim]Im)、氢氧化1-烯丙基-3-甲基咪唑([Amim]OH)在甘油与碳酸二甲酯的酯交换反应中表现出优异的活性.其中,以[Bmim]Im离子液体为催化剂时甘油转化率为98.4%和甘油碳酸酯选择性接近100%.另外,该离子液体可以回收重复利用3次后甘油转化率仍可达92%,甘油碳酸酯选择性可近100%.此碱性离子液体催化方法具有反应结果较好、产物分离简单、条件温和以及环境友好等特点.     

功能化离子液体的制备及其在合成中的应用

功能化离子液体;手性离子液体;酸性离子液体