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。     

支撑液膜在线萃取富集流动注射荧光光度法测定水中痕量苯酚

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, 建立了支撑液膜在线萃取富集流动注射荧光光度法测定水中痕量苯酚的新方法. 对实验条件进行了优化. 方法的检出限为0.4 μg/L, 线性范围为1～180 μg/L.     

支撑液膜在线萃取富集流动注射分光光度法测定水中痕量苯胺

选用无毒性的磷酸三丁酯为载体，煤油为膜溶剂的支撑液膜萃取体系，建立了支撑液膜在线萃取富集流动注射分光光度法测定河水中苯胺的新方法。对实验条件进行了优化。实验结果表明：在内相pH=2,外相pH=11，膜相组成为15%TBP-85%煤油，富集时间为13min的最优条件下，方法的检出限为0.04mg/L；线性范围为0.1-4mg/L。应用于河水中痕量苯胺的检测，结果满意。     

支撑液膜在线萃取富集流动注射分光光度法测定水中的痕量铅

研究了以双硫腙为流动载体,煤油为膜溶剂的支撑液膜萃取体系,建立了支撑液膜在线萃取富集流动注射分光光度法测定水中痕量铅(Ⅱ)的新方法。优化了支撑液膜萃取富集条件,优化结果为:试样pH=6,反萃液柠檬酸浓度为0.5 mol/L,载体双硫腙浓度为0.03%,膜孔径为0.3μm,富集时间为30 m in。在此条件下,方法的检出限为0.2μg/L;线性范围为0.5~100μg/L。应用于自来水、河水和工业污水中铅(Ⅱ)的检测,结果满意。     

在线液膜萃取富集流动注射荧光光度法测定水中痕量苯胺

设计并制造了用作苯胺在线富集的夹板式液膜(SSLM)萃取的流动注射分析装置。磷酸三丁酯用作流动载体,煤油为膜溶剂,试样中苯胺在SSLM萃取单元中得到分离和富集。SSLM萃取体系中pH 3盐酸溶液用作内相,pH 11氢氧化钠溶液用作外相。TBP溶液的适宜浓度为12%,富集时间为10 min,对经富集后pH 11碱性溶液中苯胺所产生荧光的强度进行测定。激发波长eλx为282 nm,发射波长eλm为345 nm,方法的检出限为0.2μg.L-1,苯胺浓度在1~150μg.L-1之间保持线性关系。将此方法用于测定河水中苯胺,根据分析结果算得RSD值均小于5%,回收率在97.6%至100.6%之间。     

在线液液液微萃取-电动流动分析系统测定水中挥发酚类化合物总量

采用在线液液液微萃取(LLLME)富集净化和电动流动分析(EFA)系统测定水中挥发酚类化合物折合苯酚总量.EFA系统由一台自制电渗泵和4个电磁切换阀组成,计算机控制泵运作和阀切换.结果表明:在聚丙烯中空纤维膜壁上涂十二醇液膜,管内充10 μL 0.25 mol/L NaOH反萃液,试样以2.0 mL/min流量流经萃取通道7.5次循环,1.0 mL样品体积的富集倍数为53,分析时间为 9 min,挥发酚类化合物折合浓度线性范围为9.4×10-3～5.7 mg/L苯酚,检出限为3 μg/L苯酚,远低于一和二级污水排放中挥发酚类化合物的最大允许量;6.0 mL样品体积的富集倍数为300,挥发酚类化合物折合浓度线性范围为1.7×10-3～1.0 mg/L苯酚,检出限为0.6 μg/L苯酚,低于Ⅰ和Ⅱ类地面水中挥发酚类化合物的最大允许量.     

碘作氧化剂分光光度法测定水中的挥发酚

研究了以碘作氧化剂、4-氨基安替比林(4-AAP)分光光度法测定水中的挥发酚,方法的检出限为1μg/L,线性范围为2~24 g/L,相关系数为0.9995。条件优化后,方法的精密度为3.5%,加标回收率为91.3%~118.0%,方法的精密度和准确度均符合要求。     

4-氨基安替比林萃取光度法测定挥发酚的质量保证

酚类为原生质毒 ,属高毒物质 ,人体摄入一定量时 ,可出现急性中毒症状 ,长期饮用被酚污染的水 ,可引起头昏、出疹、骚痒 ,贫血及各种神经系统症状 ,水中含低浓度 (0 .1～ 0 .2ｍｇ·Ｌ-1)酚类时 ,可使生长鱼的鱼肉有异味 ,高浓度 (75ｍｇ·Ｌ-1)时则造成中毒死亡 ,含酚浓度高的废水亦不宜用于农田灌溉 ,否则会使农作物枯死或减产 ,水中含微量酚类 ,在加氯消毒时可产生特异的氯酚臭[1] 。酚类的分析方法较多 ,而各国普遍采用的为 4 氨基安替比林光度法 ,国际标准化组织颁布的测酚亦为此法 ,酚含量超过 10ｍｇ·Ｌ-1时可采用溴化容量法测定 ,…     

流动注射-光度法测定地表水中挥发酚

以国家标准GB/T 7490-1987及国际标准ISO 6439-1990中所述的测定方法及相关技术要求为基础,提出了应用流动注射技术的FI-光度法测定地表水中挥发酚的自动注程.按此改进后的方法,一次测定可在30 min以内完成.挥发酚的质量浓度在0.10 mg·L-1以内与吸光度之间保持线性关系(r=1.000 0),方法的检出限为0.001 mg·L-1,通过分析两件工作标准样品,对方法的精密度和准确度作了考核,所得测定结果与标准值相符,相对标准偏差(n=6)均小于2%.对方法的回收率作了试验,所得结果在101.5%～106.0%之间.     

水中酚的膜萃取分离流动注射技术测定的研究

本文提出了硅橡胶膜在线萃取分离流动注射技术测定水样中苯酚的方法。由于水样中的苯酚透过硅橡胶进入萃取液的萃取量随时间的增加和温度的升高而增大，故采用停流技术及升高温度以降低酚的检出限。     

Supported liquid membrane work-up in combination with liquid chromatography and electrochemical detection for the determination of chlorinated phenols in natural water samples

Summary A sample preparation method has been developed for the determination of chlorinated phenols in water. The method is based on a supported liquid membrane extraction system connected on-line to liquid chromatography with electrochemical detection. The supported liquid membrane technique utilizes a porous PTFE membrane. The membrane is impregnated with an organic solvent which forms a barrier between two aqueous phases and enables selective extraction. The technique can easily be coupled in a flow system. In this investigation five chlorinated phenols (1–5 chlorine atoms) were extracted from natural water samples. Extraction for 30 minutes resulted in detection limits of approximately 25 ng L^–1.     

High-performance liquid chromatographic determination of phenolic compounds in natural water coupled with on-line flow injection membrane extraction-preconcentration

A liquid chromatographic method for determination of trace phenolic compounds has been established, coupled with an on-line supported liquid membrane extraction-preconcentration flow-injection system. Tributyl-phosphate dissolved in kerosene was used as the carrier of the supported liquid membrane. Four phenolic compounds (phenol, catechol, resorcinol and hydroquinone) were chosen as the model compounds and the experiment conditions were optimized. Under the optimum conditions, calibrations were linear in the range of 1-500 microg/L, with good correlation coefficients (r > 0.999). The total analysis time of the system was 22 min, including the membrane extraction, liquid chromatographic separation and equilibration times.     

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.     

Hollow fiber supported ionic liquid membrane microextraction for determination of sulfonamides in environmental water samples by high-performance liquid chromatography

By using ionic liquid as membrane liquid and tri-n-octylphosphine oxide (TOPO) as additive, hollow fiber supported liquid phase microextraction (HF-LPME) was developed for the determination of five sulfonamides in environmental water samples by high-performance liquid chromatography with ultraviolet detection The extraction solvent and the parameters affecting the extraction enrichment factor such as the type and amount of carrier, pH and volume ratio of donor phase and acceptor phase, extraction time, salt-out effect and matrix effect were optimized. Under the optimal extraction conditions (organic liquid membrane phase: [C₈MIM][PF₆] with 14% TOPO (w/v); donor phase: 4 mL, pH 4.5 KH₂PO₄ with 2 M Na₂SO₄; acceptor phase: 25 μL, pH 13 NaOH; extraction time: 8 h), low detection limits (0.1–0.4 μg/L, RSD ≤ 5%) and good linear range (1–2000 ng/mL, R² ≥ 0.999) were obtained for all the analytes. The presence of humic acid (0–25 mg/L dissolved organic carbon) and bovine serum albumin (0–100 μg/mL) had no significant effect on the extraction efficiency. Good spike recoveries over the range of 82.2–103.2% were obtained when applying the proposed method on five real environmental water samples. These results indicated that this present method was very sensitive and reliable with good repeatabilities and excellent clean-up in water samples. The proposed method confirmed hollow fiber supported ionic liquid membrane based LPME to be robust to monitoring trace levels of sulfadiazine, sulfamerazine, sulfamethazine, sulfadimethoxine and sulfamethoxazole in aqueous samples.     

Direct determination of chlorophenols present in liquid samples by using a supported liquid membrane coupled in-line with capillary electrophoresis equipment

Actually there is a great trend on the development of effective analytical methods for monitoring trace levels of various phenols which can indicate, among others compounds, the water quality. A simple, inexpensive supported liquid membrane (SLM) device was used in combination with commercially available capillary electrophoresis (CE) equipment for the direct determination of chlorophenols in surface water samples. The manifold was used simultaneously to extract and preconcentrate the analytes from liquid samples. In the extraction set-up, the donor phase (4 mL) was placed in the CE vial, where a micro-membrane extraction unit (MMEU) accommodating the acceptor phase (100 μL) in its lumen was immersed. The supported liquid membrane was constructed by impregnating a porous Fluoropore Teflon (PTFE) membrane with a water-immiscible organic solvent (dihexyl ether). The extraction process was optimized with regard to the pH of the donor and acceptor phases, membrane liquid, extraction time and voltage applied to the inlet or outlet vial during extraction. The chlorinated phenols pentachlorophenol (PCP), 2,3,6 trichlorophenol (TCP) and 2,6 dichlorophenol (DCP) were thus efficiently separated by CE, using tris(hydroxymethyl)aminomethane (Tris) and an NaH₂PO₄ solution containing 1% (v/v) methanol at pH 10.5 as running buffer.     

Extraction of molybdenum by a supported liquid membrane method

This is a report on the extraction of molybdenum(VI) ions using a supported liquid membrane, prepared by dissolving in kerosene, the extractant Alamine 336 (a long-chain tertiary amine) employed as mobile carrier. A flat hydrophobic microporous membrane was utilised as solid support. Appropriate conditions for Mo(VI) extraction through the liquid membrane were obtained from the results of liquid-liquid extraction and stripping partition experiments. The influence of feed solution acidity, the carrier extractant concentration in the organic liquid film and the content of strip agent on the metal flux through membrane were investigated. It was established that maximal extraction of metal is achieved at a pH 2.0 if sulphuric acid is used in the feed solution and at a pH value over 11.0 if Na₂CO₃ is used as strip agent. Moreover, the molybdenum extraction through membrane is enhanced when a 0.02 mol l⁻¹ content of the amine carrier in the organic phase is used. The present paper deals with an equilibrium investigation of the extraction of Mo(VI) by Alamine 336 and its permeation conditions through the liquid membrane, and examines a possible mechanism of extraction.     

HPLC determination of volatile phenols in wines

Summary An alternative to the traditional solvent extraction method used to extract and rapidly quantify ethyl-and vinylphenol and ethyl-and vinylgaiacol from wine is presented. The method is based on retention of volatile phenols on adsorbants. Among the tested resins, the most efficient, AG 2-X8 (anion exchange resin), worked as well with a synthetic solution as with wines. The percolation of clarified wine adjusted to pH 9 on this resin permits, in particular, the elimination of organic acids. Phenols are not eluted after rinsing the column with 1N HCl, but are eluted with methanol after this treatment. Good recovery (91 %) and good repeatability are observed. The eluate is directly analysed by HPLC on an RP18 column after two-fold dilution in water. The four volatile phenols were completely separated and detected by UV at 280 nm with high sensitivity (20–40 ppb). No interference with other compounds were noted in the different wines analysed.     

Electromembrane extraction of peptides--fundamental studies on the supported liquid membrane

A large screening of different components in the supported liquid membrane (SLM) in electromembrane extraction (EME) was performed to test the extraction efficiency on eight model peptides. Electromembrane extraction from a 500 μL acidified aqueous sample containing the model peptides in the concentration 10 μg/mL was used. Extraction time was 5 min with an electric potential of 10 V and 900 rpm agitation of the sample vial. The samples were extracted through a hollow fiber-based SLM with different compositions of organic solvents and carriers. A small volume of acidified acceptor solution (25 μL) was after extraction analyzed directly, or with some dilution, on CE or HPLC. This article has identified mono- or di-substituted phosphate groups as the prominent group of carrier molecules needed to obtain acceptable recoveries. For the organic solvents, primary alcohols and ketones have shown promise regarding recovery and reproducibility, with some differences in selectivity. A new composition of the SLM, namely 2-octanone and tridecyl phosphate (90:10 w/w) has proved to give higher extraction recoveries and lower standard deviation than SLMs previously reported in the literature.     

Hollow-fibre supported liquid membrane extraction for determination of fluoxetine and norfluoxetine concentration at ultra trace level in sewage samples

In this study, a method was developed for determining the concentration of the pharmaceutical fluoxetine and its metabolite, norfluoxetine, in sewage water samples. Sample preparation was performed by hollow-fibre supported liquid membrane (HF-SLM) extraction with final analysis using liquid chromatography with UV detection. Several parameters were studied including type of organic solvent, sample and acceptor pH, and salt and humic acid content. The optimised method allowed determination of the analyte at the ng/L level in sewage water. A linear plot gave a correlation coefficient better than 0.991 for both analytes and resulted in limits of detection in sewage water of 11 and 12 ng/L, for fluoxetine and norfluoxetine, respectively. The enrichment factor was over 1700 for both analytes in sewage water. The repeatability and reproducibility were better than 8% and 17%, respectively. The developed methodology was used to study daily variations of fluoxetine and norfluoxetine in municipal sewage streams. Norfluoxetine has been detected for the first time in sewage water and a preliminary analysis gave average concentrations of 150 and 225 ng/L for norfluoxetine and fluoxetine, respectively.