离子液体毒性、生物降解性及绿色离子液体的设计与合成

离子液体作为溶剂或催化剂在化学反应、分离过程、电化学及其它领域中已有广泛的应用. 离子液体一直被认为是一种环境友好的“绿色溶剂”, 最近几年其潜在的毒性、生物降解性及绿色离子液体的设计与合成才引起人们的重视. 综述了近年来该领域的研究进展.     

离子液体催化CO_2和环氧化合物的研究进展

离子液体是一类新型的催化CO_2环加成反应的催化剂,因其具有结构可设计性、催化活性高、绿色高效等优点而被广泛应用于催化合成环状碳酸酯.本文主要综述了近几年来各种常规型离子液体及功能化离子液体对CO_2和环氧化合物反应的催化性能的研究进展,其中常规型离子液体主要有咪唑类、季铵盐、季鏻盐、吡啶类等离子液体,而功能化离子液体包括氨基功能化、羟基功能化、羧基功能化、氨基酸类等离子液体.同时对各类离子液体催化CO_2与环氧化合物合成环状碳酸酯的研究中存在的问题进行了分析,并对其应用前景进行了展望.     

离子液体在生物质利用方面的应用

能源和环境危机日益严重,生物质作为唯一可再生的碳源,其开发利用备受关注.同时离子液体因其不挥发、较好的稳定性和可重复利用等优点,可作为新型绿色溶剂.近年来,离子液体和生物质利用的研究交叉渗透,研究者们完成了一系列离子液体在生物质利用方面的应用研究.本文主要从生物基离子液体和离子液体作为生物质利用的介质两方面对该研究进行...     

离子液体的进展——绿色制备及在环境修复中的应用研究

近年来,离子液体由于其独特的性能在实验室和工业领域得到广泛研究,并展示出良好的应用前景.同时,一系列离子液体绿色制备技术被开发设计出来,极大地改变了离子液体的研究面貌.本文综述了离子液体的绿色制备及在环境修复中的应用进展.离子液体的绿色合成主要途径有,原子经济性反应、绿色原材料合成、绿色溶剂合成、化工过程强化技术及计算机辅助设计,表现出合成效率高、产品质量好、废物产生量少、能耗低、合成条件温和等特点.离子液体的绿色制备不仅使离子液体更加丰富多彩,而且使其"从头到脚"成为一种绿色溶剂和绿色功能材料.离子液体在环境修复的典型特点和独特优势表现在:在水体修复方面,具有分离效率高、不产生二次污染、耗材少等特点;在土壤修复中,可以有效削弱污染物质在土壤中的毒性;在大气修复中,在消除污染物的同时,有时可以实现其资源化利用.展望了离子液体在绿色制备和环境修复的未来发展趋势.     

1-丁基-3-甲基咪唑甲磺酸盐离子液体对聚碳酸酯阻燃性能及热降解行为的影响

随着绿色化学概念的提出,在全世界范围内形成了离子液体的研究热潮。离子液体具备非挥发性或"零"蒸气压;低熔点;宽液程;高热稳定性;酸碱可调性;可循环使用性;非燃性等优良特性,使离子液体被公认为是符合绿色化学理念的溶剂与材料。聚碳酸酯(PC)作为重要的工程塑料,很多应用对其有阻燃性能有较高要求。而传统用于PC的阻燃剂不具备很好的环境友好性。     

离子液体在阻燃领域的研究进展

离子液体作为一种新兴的绿色溶剂,具有低蒸气压、高热稳定性、良好的可设计性和非燃烧性等优点,在各个领域得到了广泛的应用。随着人们对消防安全的日益关注,研究和开发无(低)毒、低烟、绿色环保的阻燃材料逐渐成为阻燃领域的发展方向。本文简要综述了近几年来离子液体在阻燃领域的最新研究进展,重点介绍了离子液体在高分子基体中的阻燃机理和进展,同时也介绍了离子液体在棉织物及锂离子电池等材料中的阻燃应用,最后对其发展前景作了展望。     

离子液体的绿色合成及环境性质

针对离子液体的绿色合成及应用过程中的环境性质,对离子液体常规合成的改进、无溶剂的微波和超声辅助合成等方面的研究进展进行了总结,对离子液体在生物体内的累积程度、离子液体的毒性和降解性等方面的研究进行了介绍。     

离子液体的前沿、进展及应用

离子液体作为一类新型绿色介质,近年来获得了突飞猛进的发展.离子液体的多项应用研究正在进行中试或工业性试验,甚至已经进入产业化阶段.推动离子液体研究迅速发展的直接动力来源于国际社会对清洁生产、环境保护、循环经济的强烈愿望,以及离子液体本身的科学探索价值和巨大的应用潜力.离子液体不仅可替代传统有机溶剂或酸碱成功用作化工反应和分离的新介质,而且展示了作为新型磁性材料、纳微结构功能材料、润滑材料、航空航天推进剂等潜力,甚至有望成为食品和医药.     

新型室温离子液体六烷基胍盐的制备及性质

近年来 ,离子液体 (IL)作为“绿色”溶剂受到学术和工业界的关注 .英国 BP公司和法国的 IFP等研究机构从 2 0世纪 80年代起就开始探索离子液体作为溶剂与催化剂的可能性 ,至今在离子液体体系中已实现了许多催化反应 [1～ 5] .室温离子液体 (RTIL S)是指在常温下呈液态的熔盐体系 .通常由烷基吡啶或双烷基咪唑季铵阳离子与氯铝酸根、氟硼酸根及氟磷酸根等阴离子组成 .在季铵盐类离子液体中 ,咪唑盐的合成和应用研究尤为突出 .目前 ,对于既可作为溶剂又可作为催化剂的室温离子液体的合成和应用已成为研究热点 [6 ] ,如室温离子液体 [EMI…     

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.     

Porous ionic liquids: synthesis and application

Solidification of fluidic ionic liquids into porous materials yields porous ionic networks that combine the unique characteristics of ionic liquids with the common features of polymers and porous materials. This minireview reports the most recent advances in the design of porous ionic liquids. A summary of the synthesis of ordered and disordered porous ionic liquid-based nanoparticles or membranes with or without templates is provided, together with the new concept of room temperature porous ionic liquids. As a versatile platform for functional materials, porous ionic liquids have shown widespread applications in catalysis, adsorption, sensing, actuation, etc. This new research direction towards ionic liquids chemistry is still in its early stages but has great potential.     

Self-healing Ionic Liquid-based Electronics and Beyond

Owing to the advantages of non-volatility, outstanding fluidity and easy recyclability, ionic liquid-based electronics, such as thermometer, strain sensors and thermoelectric converters, have been growing as attractive alternatives to traditionally solid electronics. The fluidic character endows the ionic liquid-based circuit with self-healing ability, satisfying the needs of longer lifetime and less waste generation for electronics, while at the same time brings the risk of leakage. Avoiding th...     

基于离子液体的绿色催化过程

离子液体为构建绿色催化反应过程提供了新途径.本文简要评述了离子液体在几个代表性催化反应中的研究进展,如CO2羰基化、烷基化、酯交换、氧化、CO2加氢、共聚以及PET降解等;分析讨论了离子液体的特点和优势,如提高反应活性、降低废物排放以及简化分离等,并对离子液体催化反应的未来发展方向进行了展望.     

High‐throughput microscale extraction using ionic liquids and derivatives: A review

Ionic liquids and derivatives—mainly polymeric ionic liquids and magnetic ionic liquids—have been extensively used in microscale extraction over the past few years. Current trends in analytical sample preparation gear toward linking microextraction approaches with high‐throughput sample processing to comply with green analytical chemistry requirements. A variety of high sample throughput strategies that are coupled to both ionic‐liquid‐based solid‐phase microextraction and ionic liquid‐based liquid‐phase microextraction are herein reported. The review is focused on microscale extraction methods that use (i) custom‐made and dedicated extraction devices, (ii) parallel extraction, (iii) magnetic‐based separation, and (iv) miniaturized systems employing semi‐automatic or fully automatic flow injection methods, related micro/millifluidic devices, and robotic equipment.     

离子液体固定化材料在固相萃取中的应用研究进展

离子液体是由阴、阳离子组成的低温熔融盐,几乎没有蒸汽压,具有稳定性好、溶解能力强、结构可设计、导电性好等优良性能.离子液体作为一种广受关注的新型“绿色溶剂”,具有代替传统有机溶剂的潜力,其制备方法和应用范围研究日趋完善和多样,已广泛应用于催化化学、光电化学、材料化学和分析化学等领域.离子液体通过功能化导向设计后,可以将...     

Polymer and biopolymer mediated self-assembly of gold nanoparticles

Gold nanoparticle-polymer composites are versatile and diverse functional materials, with applications in optical, electronic and sensing devices. This tutorial review focuses on the use of polymers to control the assembly of gold nanoparticles. Examples of synthetic polymers and biopolymers are provided, as well as applications of the composite materials in sensing and memory devices.     

离子液体在生物工程方面的进展

离子液体具有不挥发性、非易燃性、离子电导率高、物化性能稳定、电化学窗口宽、结构多样性与可设计性等诸多优良特性,近年来已在电化学、生物、绿色化学等领域发挥着至关重要的作用。本文综述了离子液体在生物方面的一些应用：作为理想的载体将目标基因或者药物运送到靶细胞中达到治疗的目的;探究离子液体的毒性对生物体的影响从而达到杀灭癌细胞等特殊细胞或绿色降解的目的;利用其电催化活性好、灵敏度高等特性制成生物传感器用于电化学检测;将离子液体作为核酸分离的载体,使得核酸的分离的过程简化、效率提高。     

核磁共振波谱技术在室温离子液体研究中的应用*

室温离子液体作为一种绿色溶剂和功能材料,越来越引起人们的重视,其研究手段也越来越多。本文着重概述了核磁共振方法在测定离子液体的结构、纯度及性质,研究离子液体阴阳离子间的相互作用、离子液体与其他化合物的相互作用、离子液体及其在混合体系中的动力学特征、离子液体在溶液中的聚集行为,以及测定离子液体的热力学参数中的应用。     

Ionic Liquids Made with Dimethyl Carbonate: Solvents as well as Boosted Basic Catalysts for the Michael Reaction

This article describes 1) a methodology for the green synthesis of a class of methylammonium and methylphosphonium ionic liquids (ILs), 2) how to tune their acid–base properties by anion exchange, 3) complete neat‐phase NMR spectroscopic characterisation of these materials and 4) their application as active organocatalysts for base‐promoted carbon–carbon bond‐forming reactions. Methylation of tertiary amines or phosphines with dimethyl carbonate leads to the formation of the halogen‐free methyl‐onium methyl carbonate salts, and these can be easily anion‐exchanged to yield a range of derivatives with different melting points, solubility, acid–base properties, stability and viscosity. Treatment with water, in particular, yields bicarbonate‐exchanged liquid onium salts. These proved strongly basic, enough to efficiently catalyse the Michael reaction; experiments suggest that in these systems the bicarbonate basicity is boosted by two orders of magnitude with respect to inorganic bicarbonate salts. These basic ionic liquids used in catalytic amounts are better even than traditional strong organic bases. The present work also introduces neat NMR spectroscopy of the ionic liquids as a probe for solute–solvent interactions as well as a tool for characterisation. Our studies show that high catalytic efficacy of functional ionic liquids can be achieved by integrating their green synthesis, along with a fine‐tuning of their structure. Demonstrating that ionic liquid solvents can be made by a truly green procedure, and that their properties and reactivity can be tailored to the point of bridging the gap between their use as solvents and as catalysts.     

Neuromorphic Liquids,Colloids, and Gels: A Review

Advances in flexible electronic devices and robotic software require that sensors and controllers be virtually devoid of traditional electronic components, be deformable and stretch-resistant. Liquid electronic devices that mimic biological synapses would make an ideal core component for flexible liquid circuits. This is due to their unbeatable features such as flexibility, reconfiguration, fault tolerance. To mimic synaptic functions in fluids we need to imitate dynamics and complexity similar to those that occurring in living systems. Mimicking ionic movements are considered as the simplest platform for implementation of neuromorphic in material computing systems. We overview a series of experimental laboratory prototypes where neuromorphic systems are implemented in liquids, colloids and gels.