氰乙基纤维素/二甲基甲酰胺液晶溶液的流变行为

本文通过测定不同浓度的溶液在不同温度和切变速率下的粘度,讨论了氰乙基纤维素/二甲基甲酰胺溶液的流变行为。溶液的流动曲线表明,该溶液是一种假塑性液体。在浓度较高时,存在屈服现象,屈服应力的大小与浓度和温度有关。溶液的浓度—粘度曲线表示出典型的液晶行为。粘度与浓度的关系和屈服应力与浓度的关系相似。溶液的临界浓度随温度的升高而增加。在单相区(各向同性相或液晶相),粘度随温度升高而降低,表观流动活化能大于零。但在两相区,粘度随温度的升高而增大,表观流动活化能小于零。该实验得到的临界浓度与通过光学的方法所得的临界浓度是一致的。     

在复杂流体中的相平衡

复杂流体表现出与一般溶液不同的特性,它们常呈现更丰富和多变的性质和相行为.认识和了解复杂流体丰富多彩的相平衡知识,对于解决生产中存在的问题有重要意义.本文以复杂流体中存在的自组装结构、特殊相互作用及其独特的相行为目标,分别介绍脂质体溶液和盐湖卤水溶液中呈现的特殊相互作用、自组装体结构及其相平衡.从化学热力学的角度出发,探索在这些复杂流体中组分可能形成的自组装体,以及这些自组装体对复杂流体相行为的影响.     

手性离子对色谱法

阐述了手性离子对色谱分离药物对映体的基本原理。在ＨＰＬＣ流动相中加入光学纯反离子可与流动相中的对映体生成非对映体复合物（离子对）,离子对复合物之间具有不同的稳定性和分配性质,并可与固定相发生不同的静电、疏水和氢键作用,进而差速迁移得以分离。影响方法立体选择性的主要因素有：反离子的性质（酸碱性、亲脂性、光学纯度）、反离子的浓度、流动相的组分、流动相的流速、固定相的性质和色谱柱的温度等。     

光响应离子液体的结构与性能调控

光响应离子液体是一类兼具光刺激响应和离子液体双重特性的功能材料。在紫外/可见光照下,这类“智能型”离子液体的结构会发生变化,从而引起物理化学性质和相关体系性能的显著变化,以满足某些特定过程的需要。光刺激具有信号稳定、刺激部位精准、可快速切换、刺激过程不引入其他物质等优点,在刺激响应离子液体的结构与性质调控中具有独特的优势。本文以光响应离子液体的结构-性质-性能关系为主线,对光响应离子液体的光致异构化、物理化学性质调制、簇集行为调控、光致相转移及离子液体参与构筑的光响应乳液相行为调控等方面的研究进展进行了评述,分析了该领域研究中存在的主要问题,并对其发展前景进行了展望。     

离子液体作高效液相色谱流动相添加剂分离测定芳香族羧酸

以离子液体作反相高效液相色谱流动相添加剂,建立了分离测定对氨基苯甲酸、邻苯二甲酸、对羟基苯甲酸、水杨酸、苯甲酸、邻甲苯甲酸6种芳香族羧酸的方法。以C18反相色谱柱为分离柱,采用紫外检测方法,以离子液体作高效液相色谱流动相添加剂,考察了检测波长、甲醇含量、离子液体溶液的pH值、离子液体烷基链长度以及离子液体溶液浓度等分离及测定条件。优化得到的色谱条件为:以甲醇和1.0mmol/L 1-丁基-3-甲基咪唑四氟硼酸盐水溶液(pH 3.0)(体积比40∶60)为流动相;检测波长240 nm;流速1.0 mL/min;柱温30℃。在优化条件下对6种芳香族羧酸进行梯度洗脱,约在16.5 min内分离完全;在5~120 mg/L范围内,线性系数均在0.999以上;检出限为0.026~0.082 mg/L。方法的平均加标回收率为98.3%~103.8%,相对标准偏差不高于0.63%。将该方法应用于药品复方紫荆皮水杨酸溶液和足君清酊剂中芳香族羧酸的测定,结果满意。     

静电离子色谱用于硼酸溶液中硼不同形态组分分离的研究

改进了把胆汁酸诱导体胶束(CHAPSO)涂覆在ODS载体上制备静电离子色谱固定相的方法.以纯水为流动相,采用示差折光检测器,研究了硼酸溶液中硼的形态、分离条件,并对色谱峰进行了解析.此外,还对硼酸溶液中硼离子、硼分子的色谱保留行为进行了探讨.     

由纯组元性质预估过量体积和过量焓——新关联方程的提出

在各种预估溶液过量性质的方法中,以统计力学为基础的Flory法常被采用。在此基础上,Pollin和Fried按虚拟双流体理论所提出的方法使预估的准确性有所提高。其他还可以提到Lieberman以Van der Waals方程为基础的预估方法。本文的目的是从反映液体实际PVT性质的函数关系出发,提出相应的状态方程,并用于推导预估液体溶液过量性质的新关联方程。     

手性流动相添加剂法拆分氧氟沙星对映体的热力学研究

采用配位体金属离子交换剂作为手性流动相添加剂,以L-苯丙氨酸和硫酸铜溶液为手性配体流动相,考察了293~313K温度范围内,氧氟沙星对映体在C18高效液相色谱柱上拆分的热力学性质。结果表明,在实验范围内,随着温度的升高,对映体的保留时间、分离度和选择性因子均减少;用lnk′对1/T作图,得Van’t Hoff曲线具有良好的线性关系,相关系数R0.999。计算了氧氟沙星对映体在色谱柱分离的焓变、焓变差值和熵变差值等热力学参数。在实验温度范围内,氧氟沙星对映体满足︱△S,R△H0︱︱T△S,R△S0︱,说明手性拆分过程为焓控过程。     

大环糖肽抗生素键合相高效液相色谱法拆分7种氨基带保护基的氨基酸对映体

采用高效液相色谱法在装有大环糖肽抗生素键合相的手性柱上拆分了7种氨基带有芴甲氧羰基(fluorenylmethoxycarbonyl,Fmoc)保护的氨基酸对映体。比较了Fmoc-缬氨酸和相应的不带保护基的缬氨酸对映体在不同流动相体系中的色谱保留行为;考察了甲醇-醋酸-三乙胺流动相体系中醋酸和三乙胺的浓度以及它们二者的浓度之比对N-Fmoc氨基酸对映体拆分效果的影响。实验结果表明分离温度及流动相流速的变化也会对分离结果产生影响。该法简便快速,已成功地用于这类氨基酸的光学纯度测定。     

β-环糊精流动相添加剂在手性分离中的应用综述

介绍了β-环糊精的基本性质,综述了β-环糊精及其衍生物作为流动相添加剂在高效液相色谱和高效毛细管电泳手性分离中的应用,并探讨了其作为手性流动相添加剂的特点.指出β-环糊精是良好的手性识别体,不仅可作为色谱手性固定相,还可作为流动相添加剂,用于手性对映体的拆分.     

Continuous fabrication of biocatalyst immobilized microparticles using photopolymerization and immiscible liquids in microfluidic systems

We report a novel technique for manufacturing polymeric microparticles containing biocatalysts by the behavior of immiscible liquids in microfluidic systems and in situ photopolymerization. The approach utilizes a UV-polymerizable hydrogel/enzyme solution and an immiscible oil solution. The oil and hydrogel solutions form emulsions in pressure-driven flow in microchannels at high values of the dimensionless capillary number (Ca). The resultant hydrogel droplets are then polymerized in situ via exposure to 365 nm UV light. This technique allows for the generation of monodisperse particles whose size can be controlled by the regulation of flow rates. In addition, both manufacturing microparticles and immobilizing biocatalysts can be performed simultaneously and continuously.     

Vortex fluidic induced mass transfer across immiscible phases

Mixing immiscible liquids typically requires the use of auxiliary substances including phase transfer catalysts, microgels, surfactants, complex polymers and nano-particles and/or micromixers. Centrifugally separated immiscible liquids of different densities in a 45° tilted rotating tube offer scope for avoiding their use. Micron to submicron size topological flow regimes in the thin films induce high inter-phase mass transfer depending on the nature of the two liquids. A hemispherical base tube creates a Coriolis force as a ‘spinning top’ (ST) topological fluid flow in the less dense liquid which penetrates the denser layer of liquid, delivering liquid from the upper layer through the lower layer to the surface of the tube with the thickness of the layers determined using neutron imaging. Similarly, double helical (DH) topological flow in the less dense liquid, arising from Faraday wave eddy currents twisted by Coriolis forces, impact through the less dense liquid onto the surface of the tube. The lateral dimensions of these topological flows have been determined using ‘molecular drilling’ impacting on a thin layer of polysulfone on the surface of the tube and self-assembly of nanoparticles at the interface of the two liquids. At high rotation speeds, DH flow also occurs in the denser layer, with a critical rotational speed reached resulting in rapid phase demixing of preformed emulsions of two immiscible liquids. ST flow is perturbed relative to double helical flow by changing the shape of the base of the tube while maintaining high mass transfer between phases as demonstrated by circumventing the need for phase transfer catalysts. The findings presented here have implications for overcoming mass transfer limitations at interfaces of liquids, and provide new methods for extractions and separation science, and avoiding the formation of emulsions.

Micron to submicron size Coriolis and Faraday wave induced high shear topological flow regimes in 45° titled rapidly rotating tubes result in high inter-phase mass transfer of immiscible liquids and spontaneous demixing.     

Layered interfaces between immiscible liquids studied by density-functional theory and molecular-dynamics simulations

We present a study of the structure in the interface between two immiscible liquids by density-functional theory and molecular-dynamics calculations. The liquids are modeled by Lennard-Jones potentials, which achieve immiscibility by suppressing the attractive interaction between unlike particles. The density profiles of the liquids display oscillations only in a limited part of the simple liquid-phase diagram (rho,T). When approaching the liquid-vapor coexistence, a significant depletion appears while the layering behavior of the density profile vanishes. By analogy with the liquid-vapor interface and the analysis of the adsorption this behavior is suggested to be strongly related to the drying transition.     

Carboxyl-functionalized task-specific ionic liquids for solubilizing metal oxides

Imidazolium, pyridinium, pyrrolidinium, piperidinium, morpholinium, and quaternary ammonium bis(trifluoromethylsulfonyl)imide salts were functionalized with a carboxyl group. These ionic liquids are useful for the selective dissolution of metal oxides and hydroxides. Although these hydrophobic ionic liquids are immiscible with water at room temperature, several of them form a single phase with water at elevated temperatures. Phase separation occurs upon cooling. This thermomorphic behavior has been investigated by (1)H NMR, and it was found that it can be attributed to the temperature-dependent hydration and hydrogen-bond formation of the ionic liquid components. The crystal structures of four ionic liquids and five metal complexes have been determined.     

Control and applications of immiscible liquids in microchannels

Photolithography was used in combination with photocleavable self-assembled monolayers to pattern surface free energies inside microchannels enabling the control of the boundary between immiscible liquids. While aqueous solutions are confined to the hydrophilic pathways by surface forces alone, organic liquids are confined to the hydrophobic region only if the aqueous liquid first occupies the hydrophilic region. In this way, stable liquid boundaries between immiscible liquids are possible as long as the pressures are maintained below critical values. The maximum pressures are determined by the interfacial tension of the aqueous solution and organic liquid, channel depth, and advancing contact angle (theta;(a)). Experimental results on maximum pressures are in good agreement with the analytical values. The ability to confine and position the boundary between immiscible liquids inside microchannels leads to a broad range of applications in microfluidic systems, which is exemplified by fabrication of a semipermeable membrane in a surface-patterned channel via interfacial polymerization.     

When does a diblock copolymer probe the interfacial rheological effect?

Lateral diffusion of diblock copolymer residing on the interfaces between two immiscible liquids is investigated at single molecular level. Fluorescence correlation spectroscopy was used to study the diffusion of fluorescence-labeled diblock copolymer, polystyrene-b-polyisoprene, at the interface formed between two immiscible liquids. The interfaces are formed between N,N-dimethylformamide (DMF) and a few immiscible liquids, n-alkane and polyisoprene. Interfacial diffusion coefficient of the diblock copolymer probe is found to decrease monotonously with the increase of the molecular length of the interface constituting liquids. The decrease of diffusion coefficient follows the prediction by Einstein relation using the viscosity of the constituting liquids as the variables only for interfaces between DMF and very small n-alkanes. For interfaces formed between DMF and bigger alkanes and especially between DMF and polyisoprene, the diffusion coefficient is much higher than the calculated value, indicating that the probe molecule starts to probe the much less viscous interfacial region because the interfacial width gets larger, whose thickness is comparable to the molecule size of the liquids.     

Surfactant-enhanced liquid-liquid extraction in microfluidic channels with inline electric-field enhanced coalescence

Continuous microfluidic liquid-liquid extraction is realized in a microfluidic device by generating emulsions with large interfacial areas for mass transfer, and subsequently breaking these emulsions using electric fields into easily separated segments of immiscible liquids (plugs). The microfluidic device employs insulated electrodes in a potassium hydroxide-etched channel to create large electric fields (100 kV m(-1)) that drive coalescence of the emulsion phase. The result is a transition from disperse to slug flow that can then readily be separated by gravity. Extractions of phenol and p-nitrophenol from an aqueous to hexane-surfactant solution serve as model systems. In addition to the increased surface area in the emulsion, extraction efficiency is enhanced by reverse micelles resulting from the presence of surfactants. The surfactant concentration is varied approximately 1-10 wt% and a general two-parameter model is developed to quantify the extraction behavior and demonstrate the effectiveness of reverse micelle enhanced extraction.     

稳态双曲流场中液/液混合的粘性液滴哑铃分散模型

通过对稳态双曲流场中液／液混合体系分散相液滴所受分散作用力的分析，建立了粘性液滴的哑铃分散模型．趋于将两粘性液滴分开的分散作用力与粘度比、流场类型和强度、液滴半径、哑铃取向和尺寸有关．该模型解释了流场类型与分散作用的关系．流场类型对液滴的分散具有很大影响，在纯应变拉伸流场中分散作用力是简单剪切流场中的两倍，因而对于液滴的分散，拉伸流场较简单剪切流场更有效，这与以前的实验结论符合．当体系粘度比趋于无穷大时本模型转化为刚性哑铃分散模型     

Application of mutually immiscible ionic liquids to the separation of aromatic and aliphatic hydrocarbons by liquid extraction: a preliminary approach

The recently discovered class of ionic liquids--mutually immiscible ionic liquids--are explored in this work for their first practical application: the separation of aromatic and aliphatic hydrocarbons by solvent extraction. For this preliminary approach, benzene and hexane were chosen as representatives of each group of hydrocarbons; the ionic liquids 1-ethyl-3-methylimidazolium bis( (trifluoromethyl)sulfonyl)amide and trihexyl(tetradecyl)phosphonium bis( (trifluoromethyl)sulfonyl)amide, which are both liquid at room temperature and hydrophobic, were selected as potential solvents. Liquid-liquid equilibrium experiments were carried out at 25 degrees C for the quaternary system formed by the two hydrocarbons and the two ionic liquids. Typical extraction parameters were calculated and analysed in order to evaluate the possibilities of the mutual immiscible ionic liquids in accomplishing the separation target. A comparison with the case of using just one of the ionic liquids was made.