酸性有机磷类萃取剂单分子膜的气-液界面行为:亚相pH和铺展溶剂的影响

液-液两相萃取过程中,有机磷类萃取剂分子的界面行为决定了其以何种形式参与到界面萃取反应中.为了阐明萃取剂分子界面行为的变化特点,采用Langmuir单分子膜技术研究了单分子膜中P507分子在气-液界面的吸附和聚集行为随亚相pH、有机溶剂极性的变化.通过测定表面压-分子面积等温线,并采用界面红外反射吸收光谱（IRRAS）分析表征气-液界面P507分子间相互作用,结果发现,以正己烷作铺展溶剂时,随亚相pH的降低,P507单分子膜质子化程度提高,P507分子极性端水化能力削弱,分子间相互作用增强,单分子膜中形成含有分子间氢键的聚集体.但采用极性有机溶剂（二氯甲烷和氯仿）铺展P507单分子膜,膜内P507分子界面聚集状态发生变化.铺展溶剂极性增强,单分子膜内会含有更多极性端水化能力强的P507分子单体,并且亚相pH降低,单分子膜不会出现类似正己烷条件下的π-A曲线收缩和P-O-H基团峰位红移现象.这证实了有机铺展溶剂极性可以改变P507单分子膜中分子界面存在形式和聚集状态.本工作为深入理解溶剂萃取过程中水油两相界面处酸性有机磷类萃取剂分子的聚集行为变化及其对界面反应活性的影响机制奠定了基础.     

液膜萃取本地产烟叶中烟碱的研究

采用液膜萃取技术对本地产烟叶的烟碱进行了分析,膜载体使用0.45 μm的PVC油膜和定性滤纸,浸泡膜载体的溶剂分别使用十一烷,十六烷和CHCl3.液膜萃取后的样品经GC/MS分析表明,滤纸作为膜载体的萃取效率明显高于PVC油膜;相同膜载体的情况下,以CHCl3浸泡的膜载体的萃取效果比较好.文中还对两种膜载体在不同溶剂浸泡下的烟碱的萃取效率以及最佳萃取时间进行了研究.     

支载液膜双有机相萃取分离氧氟沙星外消旋体

基于化学热力学原理, 采用逆流分级萃取和中空纤维支载液膜技术研究了氧氟沙星外消旋体在手性环境中的萃取分离. 膜内外两相辛醇溶液中分别含有L-二苯甲酰酒石酸和D-二苯甲酰酒石酸手性选择体, 其中膜内相辛醇溶液中含有氧氟沙星外消旋体. 中空纤维膜用含有溴化十六烷基三甲胺的磷酸氢二钠/磷酸缓冲液(pH = 6.86)浸泡48 h. 改性的液膜允许氧氟沙星对映体穿过, 而手性选择体和有机溶剂不能穿过. 对中空纤维膜分级手性萃取理论, 传质性能及立体选择性进行了研究; 并建立了氧氟沙星外消旋体在中空纤维支载液膜手性分离的数学模型R/S=0.976 e^0.03NTU. 使用11个22 cm长膜器串联(传质单元数为78)逆流分级萃取, 产品光学纯度达90%以上.     

金属离子提取的支撑型液膜稳定性:膜材料研究进展

支撑液膜是一种结合膜材料与萃取体系的高效率分离技术.然而在使用过程中,溶剂与萃取载体从多孔支撑体中流失和多孔膜材料在有机相载体中不稳定,导致支撑液膜通量的衰减或选择性降低,支撑液膜表现为不稳定,目前尚未见工业化的成功案例.本文简要介绍了支撑液膜不稳定机理,从膜材料角度,综述了提高支撑液膜稳定性的方法.重点介绍了液膜凝胶...     

小分子亲水有机溶剂液-液萃取技术在分析化学中的应用进展

介绍了小分子亲水有机溶剂液-液萃取技术的基本原理、影响因素并对小分子亲水有机溶剂液-液萃取技术的发展前景进行了展望,引用文献20篇.     

平板夹心型支撑液膜萃取体系中La^3＋的迁移行为

在含ＨＥＨ（ＥＨＰ）的平板夹心型支撑液膜萃取Ｌａ＾３＋的体系中，研究了体系传质过程中的渗透系数ｐ及其影响因素。实验证明夹心型与单型支撑液膜的传质理论模型以及料液酸度和反萃液酸度对传质渗透系数的影响基本一致。当体系料液的ｐＨ在３．５￣４．２之间时，体系的渗透系数ｐ趋于稳定；ｐ随反萃液酸度的增加而增大，当反萃液酸度大于４．０ｍｏｌ／Ｌ时，ｐ趋于恒定；比较了用不同材料和厚度的夹心型支撑液膜体系萃取ｌａ２     

分散液液微萃取技术在食品分析中的应用进展

近年来,分散液液微萃取作为一种新型液相微萃取(LPME)技术受到广泛关注。该技术具有操作简单、有机溶剂用量少、富集倍数高等显著优点,已被广泛用于各类样品基质中无机和有机分析物的提取。但由于传统分散液液微萃取技术的萃取剂以高毒性有机溶剂为主,且选择性差,从而严重限制了该技术的应用。为此,最近几年发展了许多操作模式,如低密度萃取剂分散液液微萃取、悬浮固化分散液液微萃取、调节萃取剂密度的分散液液微萃取、离子液体-分散液液微萃取、水溶液作为萃取剂的反相分散液液微萃取等。该文综述了分散液液微萃取技术原理、萃取过程和影响因素(如萃取剂与分散剂种类和体积、p H值、离子强度、萃取时间等),并对其在食品分析中的应用进展进行了系统总结。     

在线液膜萃取富集流动注射分光光度法测定水中挥发酚

选用无毒性的磷酸三丁酯为流动载体，煤油为膜溶剂的液膜萃取体系，建立了液膜在线萃取富集流动注射分光光度法测定水中挥发酚的新方法。对实验条件进行了优化，在最优条件下，方法的检出限为0．0007mg/L；线性范围为0．001～0．01mg/L。应用于自来水及河水中挥发酚的检测，结果满意。     

N_(235)二甲苯-醋酸铵-液膜体系萃取Cd(Ⅱ)的研究

本文研究了反萃剂、料液 HCl浓度、温度、 N_(235)浓度对 N_(235)二甲苯醋酸铵大块液膜体系迁移 Cd~(2＋)的影响。当膜相添加不同浓度的表面活性剂 Span 80时，测定了膜料液界面的萃取反应表观速率常数 k_1和膜反萃相界面的反萃取表观速率常数 k_2，并进行了相应的动力学分析。实验证明， Cd~(2＋)的迁移可用两个连续单向不可逆的一级反应来描述。在本文的液膜体系中， Cd2＋的跨膜迁移和 H＋的同向迁移耦合。     

微流控芯片微孔膜液-液萃取系统

微流控芯片(Microfluidic chip)是微全分析系统(MTAS)研究中最为活跃的领域和发展前沿,在仪器微型化方面展现出很多优点^[1].Kitamori等^[2,3]根据多相层流无膜扩散分离技术建立了芯片上的微流控液-液萃取分离系统,对芯片上的液-液萃取方法进行了系统的研究.     

Extraction of organic compounds with room temperature ionic liquids

Room temperature ionic liquids are novel solvents with a rather specific blend of physical and solution properties that makes them of interest for applications in separation science. They are good solvents for a wide range of compounds in which they behave as polar solvents. Their physical properties of note that distinguish them from conventional organic solvents are a negligible vapor pressure, high thermal stability, and relatively high viscosity. They can form biphasic systems with water or low polarity organic solvents and gases suitable for use in liquid–liquid and gas–liquid partition systems. An analysis of partition coefficients for varied compounds in these systems allows characterization of solvent selectivity using the solvation parameter model, which together with spectroscopic studies of solvent effects on probe substances, results in a detailed picture of solvent behavior. These studies indicate that the solution properties of ionic liquids are similar to those of polar organic solvents. Practical applications of ionic liquids in sample preparation include extractive distillation, aqueous biphasic systems, liquid–liquid extraction, liquid-phase microextraction, supported liquid membrane extraction, matrix solvents for headspace analysis, and micellar extraction. The specific advantages and limitations of ionic liquids in these studies is discussed with a view to defining future uses and the need not to neglect the identification of new room temperature ionic liquids with physical and solution properties tailored to the needs of specific sample preparation techniques. The defining feature of the special nature of ionic liquids is not their solution or physical properties viewed separately but their unique combinations when taken together compared with traditional organic solvents.     

A Combined Approach Employing Soxhlet Extraction and Linear Gradient Elution Reversed-Phase HPLC for the Fingerprinting of Soil Organic Matter According to Hydrophobicity

This paper reports the results of a study carried out to evaluate the potentiality of combining selective solvent extraction and linear gradient elution reversed-phase high performance liquid chromatography (RP-HPLC) for characterizing soil organic matter on the basis of polarity of its constituting organic compounds. Such approach comprises the sequential extraction of soil organic matter with organic solvents of increasing polarity in a Soxhlet extractor and the subsequent separation of each extract by RP-HPLC. Accordingly, each soil sample has been subjected to cycles of sequential extraction with n-hexane, dichloromethane, ethyl acetate, and methanol. Each sample extracted by one of the four solvents have been dried in a rotary evaporator device at 40°C and then dissolved again in the proper volume of extraction solvent to obtaining sample solutions of concentration ranging from 5.0 to 15 mg ml⁻¹. These sample solutions have been subjected to RP-HPLC separation using a Supelcosil LC-ABZ column that has been eluted by a linear acetonitrile gradient in water, having the same profile for all samples. The study has evidenced the possibility of producing highly repeatable chromatographic profiles, which are correlated to the polarity of organic solvents employed for extracting the organic matter in the Soxhlet extractor.

     

Continuous flow liquid membrane extraction: a novel automatic trace-enrichment technique based on continuous flow liquid-liquid extraction combined with supported liquid membrane

Combining the continuous flow liquid-liquid extraction (CFLLE) and supported liquid membrane (SLM) extraction, a novel aqueous-aqueous extraction technique that we termed continuous flow liquid membrane extraction (CFLME) is developed for trace-enrichment. The analyte was firstly extracted into the organic phase in the CFLLE step, then transported onto the organic liquid membrane that formed on the surface of the micro porous membrane of the SLM equipment. Finally, it passed through the liquid membrane and was trapped by the acceptor. Aspects related to CFLME were studied by using dichloromethane as liquid membrane, and sulfonylurea herbicides as model compounds. An enrichment factor of over 1000 was obtained when 10 μg l⁻¹ of MSM was enriched for 120 min by this technique. The drawbacks of only a few organic solvents can be selected as liquid membrane with a limited lifetime in SLM operation was overcome. In this CFLME method, almost all solvents that used in the conventional liquid-liquid extraction (LLE) can be adopted and the lifetime of liquid membrane is no longer a problem.     

Membrane-based solvent extraction for selective removal and recovery of metals

A membrane-based solvent extraction process was developed for selective removal and recovery of metals from aqueous solutions. The process utilizes microporous membranes as an interface between an aqueous solution and organic solvents containing liquid ion exchangers. Metal ions are transported from the aqueous solution to the organic phase at the interface created in the pores of membrane. The organic solvent, which is loaded with metal ions in the extraction module, is regenerated in contact with the stripping solution in the stripping module. One important feature of this process is the stability of the membrane system, which results from using an aqueous—organic separator to remove aqueous solution from the organic circulating line. This process was evaluated for enrichment of copper using solvents containing LIX 64N. The process is applicable to selective recovery of metals from ore leachates or metal-containing wastewater.     

大口径毛细管气相色谱检查药物中残留溶剂的方法研究

 以药物合成中常用的 16种有机溶剂为研究对象 ,建立了用大口径毛细管柱检查残留有机溶剂的气相色谱法 ,并考察了不同极性的色谱柱及不同提取溶剂对分离与检测的影响。实验表明 ,根据原料药合成中可能存在的残留溶剂 ,选用适当的提取溶剂 ,采用大口径毛细管气相色谱法检查 ,可获得较满意的结果。     

Electromembrane extraction of verapamil and riluzole from urine and wastewater samples using a mixture of organic solvents as a supported liquid membrane: Study on electric current variations

In this study, the application of a mixture of organic solvents as a supported liquid membrane for improving the efficiency of the electromembrane extraction procedure was investigated. The extraction process was followed by high‐performance liquid chromatography analysis of two model drugs (verapamil and riluzole). In this research, four organic solvents, including 1‐heptanol, 1‐octanol, 2‐nitrophenyl octyl ether, and 2‐ethyl hexanol, were selected as model solvents and different binary mixtures (v/v 2:1, 1:1 and 1:2) were used as the supported liquid membrane. The mixture of 2‐ethyl hexanol and 1‐otanol (v/v, 2:1) improved the extraction efficiency of model drugs by 1.5 to 12 times. It was found that extraction efficiency is greatly influenced by the level of electric current. In this study, for various mixtures of organic solvents, the electric current fluctuated between 50 and 2500 μA, and the highest extraction efficiencies were obtained with low and stable electric currents. Finally, the optimized extraction condition was validated and applied for the determination of model drugs in urine and wastewater samples.     

Solvent polarity indicators: Extraction of some coumarin indicator dyes

Study of the extraction of ten different coumarins (unsubstituted, 6-methyl-, 7-methyl-, 4-hydroxy-, 7-hydroxy-, 7-hydroxy-4-methyl-, 7-methoxy-, 7-amino-4-methyl-, 7-diethyl-amino-4-methyl-, and 3-carboxy-) with nine organic solvents shows that the percentage extraction is generally high. Cyclohexanone and heptane were found to be, respectively, the most and least effective extracting solvents for the compounds under study. The results are discussed in terms of the effect of different solvent polarity parameters on the extraction process.     

Extraction of cloransulam-methyl from soil with subcritical water and supercritical CO2

Cloransulam-methyl was extracted from soil samples with supercritical CO2, subcritical water and conventional organic solvents. Supercritical CO2 was less efficient than conventional organic solvents; polarity modifiers had no impact on extraction efficiency. Extraction with supercritical CO2 exhibited a strong temperature dependence. Water was as effective as strong organic solvents for the extraction of cloransulam-methyl; however cloransulam-methyl hydrolyzed when extracted at 150 degrees C. Extraction temperature was the most important variable in increasing the efficiency and rate of extraction, while extraction pressure was not a significant variable.     

超声提取/高效液相色谱法测定土壤中的4-壬基酚

在考察不同提取方法和有机溶剂提取效率的基础上,建立了土壤样品中内分泌干扰物4-壬基酚（4-NP）的超声提取/高效液相色谱(紫外检测器)分析方法。结果显示,以二氯甲烷作提取溶剂时超声提取对土壤中4-NP的提取效率高于索氏提取法;不同有机溶剂的超声提取效率依次为二氯甲烷-甲醇(9∶1)＞二氯甲烷＞甲醇≈丙酮。样品采用二氯甲烷-甲醇(9∶1)超声提取,经硅胶柱净化、高效液相色谱检测,土壤在4-NP的高、中、低3个加标水平下的平均回收率为91%~94%,相对标准偏差为4.3%~7.2%,方法的检出限为2.0 μg/kg。采用该方法对广东省部分土壤中的4.NP进行检测,得到其含量为5.3~16 μg/kg(干重),低于河北省污水灌溉土壤中的含量。该方法简便快捷、灵敏、重现性好,适用于土壤样品中4-NP的分析。     

Selective separation of aromatic hydrocarbons through supported liquid membranes based on ionic liquids

Ionic liquids are emerging as alternative solvents for volatile organic compounds traditionally used in liquid–liquid extraction and liquid membrane separation. In this paper, we examine whether room-temperature ionic liquids as a membrane solution can be utilized for hydrocarbon separation by using a supported liquid membrane. Aromatic hydrocarbons, benzene, toluene and p-xylene were successfully transported through the membrane based on the ionic liquids. Although the permeation rates through the membrane based on the ionic liquids were less than those of water, the selectivity of aromatic hydrocarbons was greatly improved. The maximum selectivity to heptane was obtained using benzene in the aromatic permeation and 1-n-butyl-3-methylimidazolium hexafluorophosphate in the liquid membrane phase.