Determination of Nitrophenols in Water Using Dynamic Liquid‐Liquid‐Liquid Microextraction under Non‐Equilibrium Consideration

To pursue optimum condition in liquid‐liquid‐liquid microextraction (LLLME), extraction parameters dominating extraction efficiency were investigated by theoretical considerations. The theoretical considerations discussed equilibrium model for equilibrium LLLME and non‐equilibrium model for dynamic LLLME. A method described here is a dynamic LLLME technique combined with high‐performance liquid‐chromatography ultraviolet absorbance detection (HPLC/UV) to determine traces of nitrophenols in water. Analytical parameters such as organic phase, acceptor phase volume, sample agitation, extraction time, acceptor phase NaOH concentration, donor phase HCl concentration, salt addition, and absorption wavelength were identified as variable settings. Relative standard deviation (RSD, 1.8‐4.4%), coefficient of estimation (R², 0.9994‐0.9999), and detection limit (0.032‐0.065 ng mL^?1) were achieved under the variable settings. The proposed method was successfully applied to the analysis of a lake water sample, and the relative recoveries of nitrophenols from spiked water sample were up to 92.5%. The variable settings of LLLME close to optimization was responsible for an acceptable extraction efficiency.     

水样中氟罗沙星和磺胺喹噁啉的离子液体均匀提取

提出一种新的离子液体均匀提取方法,即向水样中加入可溶于水的离子液体1-己基-3-甲基咪唑四氟硼酸盐([C6MimBF4]),再加入过量六氟磷酸铵(NH4PF6),形成不溶于水的离子液体1-己基-3-甲基咪唑六氟磷酸盐([C6MimPF6]),水样中的氟罗沙星和磺胺喹噁啉被提取到[C6MimPF6]相,离心分离后,离子液体可直接用于HPLC分析.本法测得的氟罗沙星和磺胺喹噁啉的检出限分别为1.8和1.1μg/L.     

Determination of Trace Methyl Tert‐Butyl Ether in Water Samples Using Dispersive Liquid‐Liquid Microextraction Coupled with GC‐FID

A rapid and sensitive analytical method has been developed for trace analysis of methyl tert‐butyl ether (MTBE) in water samples using dispersive liquid‐liquid microextraction and gas chromatography with flame ionization detection. Factors relevant to the microextraction efficiency, such as the kind of extraction solvent, the disperser solvent and their volumes, the effect of salt, sample solution temperature and the extraction time were investigated and optimized. Under the optimal conditions the linear dynamic range of MTBE was from 0.2 to 25.0 μg L^?1 with a correlation coefficient of 0.9981 and a detection limit of 0.1 μg L^?1. The relative standard deviation (RSD%) was less than 5.1% (n = 3) and the recovery values were in the range of 97.8 ± 0.9%. Finally, the proposed method was successfully applied for the analysis of MTBE in aqueous samples.     

功能化离子液体/离子液体分散液-液微萃取测定水中苯氧羧酸类除草剂

建立了功能化离子液体/离子液体分散液-液微萃取(FIL/IL-DLLME)测定水中4种苯氧羧酸类除草剂的农药残留分析方法.离子液体[C4MIMBF4]有助于难溶于水的[C6HyMIMTf2N]在水相中形成液滴.离子对[LiWf2N]的引入有利于提高功能离子液体对分析物的提取效率,对影响萃取效率的重要因素进行选择和优化,最佳条件为:100 μL[C6HyMIMTf2N])作为提取剂,100 μL[C4MIMBF4]作为分散剂,在30℃下超声5 min,[LiTf2N]浓度为5％和样品溶液的pH=2.在最佳优化条件下,5～500 μg/L范围内线性良好,相关系数为0.9953 ～0.9996;对自来水、河水、田间水进行浓度为10和20 μg/L添加回收实验,回收率为70.2％～107.5％,相对标准偏差RSD＜10％,检出限为0.05 ～0.2 μg/L,得到满意的结果,说明本方法对于实际样本的检测具有可行性.     

超声辅助分散液液微萃取-高效液相色谱法快速测定水样中的6种农药

为实现小体积环境水祥中不同农药的准确、快速、高灵敏测定,通过研究萃取剂、分散剂的种类、体积、盐浓度及超声时间对萃取效率的影响,结合分散液液微萃取与超声萃取技术,并与高效液相色谱联用,建立了快速测定环境水样中的吡虫啉、水胺硫磷、辛硫磷、毒死蜱、哒螨灵和阿维菌素6种农药的方法.在优化的萃取条件下,检测6种农药的线性范围为10～ 600 μg/L,检出限(S/N=3)为0.8～3.1 μg/L,相对标准偏差为4.7％～11.3％,富集倍数可达到58～187倍.本方法具有良好的线性、精密度和回收率,并具有较好的实用性.     

Liquid‐Liquid Microextraction Coupled with High Performance Liquid Chromatography for Determination of Palladium

Liquid‐liquid microextraction (LLME) coupled with high performance liquid chromatography (HPLC) for the analysis of palladium is described. The analytes were extracted from a 10.0 mL aqueous sample into organic phase. The extraction time was 20 min. Factors such as pH in aqueous phase, extraction times, and stirring rate were optimised. The method was applied for determination of palladium in mixture samples. The linearity range was from 1.0 to 100 nM and the detection limit was 0.12 nM. Relative standard deviations (%, n = 5) were 0.41 to 0.74. All experiments were carried out at room temperature, 35±0.2 °C.     

分散固相萃取-超声辅助分散液液微萃取/高效液相色谱法测定土壤中溴氰菊酯残留

建立了以分散固相萃取-超声辅助分散液液微萃取为样品前处理技术,结合高效液相色谱法(HPLC)测定土壤中溴氰菊酯。样品用甲醇∶水(1∶4,V/V)提取,经布氏漏斗减压抽滤,滤液经N-丙基乙二胺(PSA)、C18、石墨炭黑粉(GCB)净化后,用氯仿萃取,超声,离心后沉积相进行HPLC测定。对分散固相萃取吸附剂的选择及影响分散液液微萃取的因素进行了优化,在最优条件下,溴氰菊酯的富集倍数达到565倍,线性范围为0.005~2.5mg/kg,线性相关系数为0.9998,检出限为0.001mg/kg,平均加标回收率为70.3%~94.5%,相对标准偏差为2.5%~4.7%。该方法具有简便快速、准确灵敏、萃取效率高等特点,可用于土壤中溴氰菊酯残留检测。     

Development of Dispersive Liquid‐Liquid Microextraction Based on Solidification of Floating Organic Drop for the Determination of Trace Cobalt in Water Samples

A liquid‐phase microextraction technique was developed using dispersive liquid‐liquid microextraction based on solidification of floating organic drop combined with flame atomic absorption spectrometry, for the extraction and determination of trace amounts of cobalt in water samples. Microextraction efficiency factors, such as the type and volume of extraction and dispersive solvents, pH, extraction time, the chelating agent amount, and ionic strength were investigated and optimized. Under optimum conditions, an enrichment factor of 160 was obtained from 10.0 mL of water sample. The calibration graph was linearin the range of 1.15‐110 μg L^?1 with a detection limit of 0.35 μg L^?1. The relative standard deviation for ten replicate measurements of 10 and 100 μg L^?1 of cobalt were 3.26% and 2.57%, respectively. The proposed method was assessed through the analysis of certified reference water or recovery experiments.     

Dispersive Liquid‐Liquid Microextraction of Cu(II) Using a Novel Dioxime for Its Highly Sensitive Determination by Graphite Furnace Atomic Absorption Spectrometry

A dispersive liquid‐liquid microextraction (DLLME) technique was proposed for the enrichment and graphite furnace atomic absorption spectrometric (GFAAS) determination of Cu²⁺ in water samples. In this method a mixture of 480 μL acetone (disperser solvent) containing 26 μg S,S‐bis(2‐aminobenzyl)‐dithioglyoxime (BAT) ligand and 20 μL carbon tetrachloride (extraction solvent) was rapidly injected by a syringe into 5 mL aqueous sample containing copper ions (analyte). Thereby, a cloudy solution formed. After centrifugation, the fine droplets containing the extracted copper complex were sedimented at the bottom of the conical test tube. This phase was collected by a microsyring and after dilution by methanol, 20 μL of it was injected into the graphite tube of the instrument for analysis. Effects of some parameters on the extraction, such as extraction and disperser solvent type and volume, extraction time, salt concentration, pH and concentration of the chelating agent were optimized. The response surface method was used for optimization of the effective parameters on the extraction recovery. Under these conditions, an enrichment factor of 312 was obtained. The calibration graph was linear in the rage of 2–50 μ L⁻¹ Cu²⁺ with a detection limit of 0.03 μg L⁻¹ and a relative standard deviation (RSD) for five replicate measurements of 3.4% at 20 μg L⁻¹ Cu²⁺. The method was successfully applied to the determination of Cu²⁺ in some spring water samples.     

离子液体分散液液微萃取/高效液相色谱法测定环境水样中7种萘二酚

建立了测定环境水样中7种萘二酚的离子液体分散液液微萃取/高效液相色谱(IL-DLLME-HPLC)分析方法。以1-丁基-3-甲基咪唑六氟磷酸盐([C4MIM][PF6])为萃取剂,水样体积为8.0 m L,研究了萃取剂用量、水相p H值、萃取时间及盐添加量对7种萘二酚萃取效率的影响。获得最佳萃取条件为:[C4MIM][PF6]体积为150μL,水相p H值为5.0~7.0,涡旋萃取时间为3 min,氯化钠添加量为0.20 g/m L。在优化条件下,7种萘二酚在一定质量浓度范围内线性关系良好,相关系数均不小于0.997 7;方法富集倍数为57倍,方法检出限(S/N=3)为0.3~1.0μg/L;阴性环境水样中3个加标水平的平均回收率为83.5%~103%,相对标准偏差(n=6)为1.1%~3.8%。该方法快速简单、准确灵敏、环保,适用于环境水样中痕量萘二酚的富集检测。     

Trace Analysis of Methyl Tert‐butyl Ether in Water Samples Using New Ultrasound‐assisted Dispersive Liquid‐liquid Microextraction and Gas Chromatography‐flame Ionization Detection

In this study, simple and efficient ultrasound‐assisted dispersive liquid‐liquid microextraction combined with gas chromatography (GC) was developed for the preconcentration and determination of methyl‐tert‐butyl ether (MTBE) in water samples. One hundred microliters of benzyl alcohol was injected slowly into 10 mL home‐designed centrifuge glass vial containing an aqueous sample with 30% (w/v) of NaCl that was located inside the ultrasonic water bath. The formed emulsion was centrifuged and 2 μL of separated benzyl alcohol was injected into a gas chromatographic system equipped with a flame ionization detector (GC‐FID) for analysis. Several factors influencing the extraction efficiency such as the nature and volume of organic solvent, extraction temperature, ionic strength and centrifugation times were investigated and optimized. Using optimum extraction conditions a detection limit of 0.05 μg L^‐1 and a good linearity (r² = 0.998) in a calibration range of 0.1‐500 μg L^‐1 were achieved. This proposed method was successfully applied to the analysis of MTBE in tap, well and a ground water sam ple contaminated by leaking gasoline from an underground storage tank (LUST) in a gasoline service station.     

Liquid‐Liquid Microextraction Coupled with High Performance Liquid Chromatography for Determination of Platinum

Liquid‐liquid microextraction (LLME) coupled with high performance liquid chromatography (HPLC) for the analysis of platinum is described. The analyte were extracted from 10.0 mL aqueous sample into organic phase. The extraction time was 20 min. Factors such as pH in aqueous phase, extraction times, and stirring rate were optimised. The method was applied for determination of platinum in mixture samples. The linearity range was from 1.0 to 100 nM and the detection limits was 0.1 nM. Relative standard deviations (%, n = 5) was 0.44 to 0.81. All experiments were carried out at room temperature, 35 ± 0.2°C.     

Combination of Dispersive Liquid‐Liquid Microextraction with Flame Atomic Absorption for Determination of Trace Ni and Co in Water Samples and Vitamin B12

A dispersive liquid‐liquid microextraction method based on the dispersion of 1,2‐dichlorobenzene as an extraction solvent into an aqueous phase in the presence of ethanol as a dispersive solvent for the preconcentration of Co²⁺ and Ni²⁺ ions is discussed. 1‐Nitroso 2‐naphtol was used as a chelating agent prior to the extraction and the preconcentrated analyte was determined by flame atomic absorption spectrometry. The effect of various experimental parameters including the extraction and dispersive solvent type and volume, pH, amount of the chelating agent, etc. on the microextraction and complex formation was investigated for finding the optimum conditions. The enhancement factors were about 61.9 and 51.8, the calibration graphs were linear in the range of 10‐150 μgL^?1 and 10‐250 μgL^?1 with detection limits of 2.42 μgL^?1 and 1.59 μgL^?1, and RSD (n = 5) of 3.08% and 2.17% for cobalt and nickel, respectively. The method was successfully applied to the determination of Co and Ni in water and vitamin B₁₂.     

分散液-液微萃取/高效液相色谱法测定水样中的痕量双酚A

建立了分散液-液微萃取与高效液相色谱联用技术测定水样中痕量双酚A(BPA)的方法. 通过对实验条件的筛选及优化, 得到最佳条件: 22.5 μL氯苯作萃取剂、0.5 mL丙酮作分散剂、0 min静止萃取时间、调节pH 3.2左右、10%离子强度及9 mL水样体积. 此条件下方法的线性范围为0.5~100 μg/L(R2=0.9941), 检出限为0.10 μg/L. 在BPA质量浓度为1 μg/L条件下, 方法回收率为87.8%~111.0%, 相对标准偏差8.3%(n=5), 富集倍数范围1905~2527. 对添加不同BPA浓度的自来水、地表水及回用中水进行分析, 回收率分别为(108±11.1)%, (107±13.2)%及(81.2±6.2)%(n=3). 在既定的色谱条件下, BPA的测定不受乙炔基雌二醇、雌二醇、雌三醇、雌酮和壬基酚等雌激素的干扰.     

分散液-液微萃取快速、直接测定有机化合物lgP值

用3-氯丙基三甲氧基硅烷对Fe₃O₄纳米球的表面进行改性, 制得表面疏水的Fe₃O₄/SiCH₂CH₃Cl纳米球. 将Fe₃O₄/SiCH₂CH₃Cl纳米球均匀预分散在正辛醇中, 利用分散液-液微萃取建立了快速、 直接测定有机化合物lgP值的新方法. 待测有机化合物可在3 min内在两相达到分配平衡, 通过磁铁吸引含有Fe₃O₄/SiCH₂CH₃Cl纳米球的正辛醇小液滴, 可实现两相快速完全分离. 在萃取过程中, 由于Fe₃O₄/SiCH₂CH₃Cl纳米球被正辛醇包围, 失去对待测化合物的吸附能力, 因此Fe₃O₄/SiCH₂CH₃Cl纳米球对测定有机化合物分配平衡的影响很小. 通过该方法测定了14种不同有机化合物的lgP值, 结果均与文献报道一致. 与其它直接测定方法相比, 该方法快速、 准确、 简单且样品消耗少.     

Determination of Cadmium and Lead in Human Teeth Samples Using Dispersive Liquid‐liquid Microextraction and Graphite Furnace Atomic Absorption Spectrometry

A new method for the determination of cadmium and lead in human teeth was developed based on dispersive liquid‐liquid microextraction preconcentration and graphite furnace atomic absorption spectrometry determination. In the proposed approach, O,O‐diethyldithiophosphate (DDTP) was used as a chelating agent, and carbon tetrachloride and methanol were selected as extraction and dispersive solvents. Some factors influencing the extraction efficiency of cadmium and lead and their subsequent determination, including extraction and dispersive solvent type and volume, pH of sample solution, concentration of the chelating agent and extraction time, were studied and optimized. Under the optimum conditions, the enrichment factor of 116 and 68 for cadmium and lead were achieved. The detection limit for cadmium and lead was 5.6 and 45 ng L^?1, and the relative standard deviation (R.S.D) was 4.5% and 3.8% (n = 7, c = 1.0 ng mL^?1), respectively. Verification of the accuracy of the method was carried out by analysis of a standard reference material (NIST 1486, bone meal). The method was successfully applied to the determination of trace amount of cadmium and lead in human teeth samples with satisfactory results.     

高效液相色谱法测定苹果中的酚类物质

利用高效液相色谱法分析了红星、秦冠、小国光、黄元帅和富士 5个苹果品种果皮和果肉中小分子酚类物质的分布情况。色谱柱为C1 8柱 ( 1 5 0mm× 4 .6mm ,Φ5 μm) ,流动相为甲醇和水 ,柱温为 30℃ ,流速为 1 .2mL min,线性梯度洗脱 ,紫外检测器波长为 2 80nm。在此色谱条件下 ,各组分均得到良好分离。标准样品的线性范围为 0 .9983～ 0 .9999,平均回收率为 75 %～ 91 %。     

分散液液微萃取-高效液相色谱法测定环境水样中2,4-二氯酚

建立了简便、快速、有效的分散液液微萃取-高效液相色谱法测定环境水样中2,4-二氯酚的分析方法。对萃取剂、分散剂的种类和体积、萃取时间、离心时间、盐浓度等影响萃取效率的因素进行了优化。方法的线性范围为1～500μg/L(r=0.9997),相对标准偏差(RSD)为3.8%(n=6),检出限为0.19μg/L。该法适用于环境水样中的痕量2,4-二氯酚的检测。     

高效液相色谱法同时测定苹果汁中6种酚类物质

建立了同时测定苹果汁中儿茶素、绿原酸、咖啡酸、表儿茶素、香豆酸和阿魏酸6种酚类物质的反相高效液相色谱方法,并对酚类物质的稳定性进行了探讨。选用Eclipse XDB-C18色谱柱(150 mm×4.6 mmi.d,5μm),以甲醇-1%乙酸水溶液作为流动相进行梯度洗脱。柱温30℃,流速1.0 mL/min,在280 nm波长下进行检测。本方法样品处理简单,具有良好的重现性和线性,相关性系数均达到0.9999,儿茶素、绿原酸、咖啡酸、表儿茶素和香豆酸和阿魏酸的回收率分别为102%~103%、94.3%~101%、102%~104%、98.4%~101%、96.2%~99.8%和102%~104%;检出限分别为20、30、10、20、7和15μg/L(S/N=3)。     

分散液液微萃取-柱前衍生-高效液相色谱法测定水样中双酚A

建立了分散液液微萃取-柱前衍生-高效液相色谱法测定水样中双酚A的分析方法.通过交互正交试验和混合型优化实验设计对影响因素(萃取剂体积、分散剂类型及其体积、水样体积、pH值及离子强度)进行了优化.优化后的分散液液微萃取条件为:60 μL萃取剂,0.4 mL分散剂(甲醇),pH 4.0;优化后的柱前衍生化条件:0.1 mL 2.0 g/L衍生剂(对硝基苯甲酰氯)、衍生化时间30 min;方法的线性范围:0.002～0.2 mg/L(r=0.9997),检出限0.007 μg/L(S/N=3);不同浓度双酚A的萃取率为59.0%～63.0%,相对标准偏差(RSD)2.5%～9.2%(n=5);水样中双酚A的加标率为86.5%～107.1%,RSD为4.0%～11.9%(n=5),其它雌激素(雌酮、雌二醇、雌三醇和17α-乙炔基雌二醇)对双酚A的测定无干扰.本方法可以对水环境中的痕量BPA进行检测,具有操作简便、快速等优点.