离子对色谱法同时分离测定吡啶及咪唑离子液体阳离子

建立了用紫外检测的反相离子对色谱梯度淋洗同时分离测定4种吡啶离子液体阳离子和5种咪唑离子液体阳离子的方法。实验采用ZORBAX Eclipse XDB-C18反相色谱柱,以离子对试剂水溶液(用柠檬酸调节pH值)+乙腈为流动相,考察了离子对试剂种类和浓度、乙腈浓度和色谱柱温度对保留的影响,探讨了相关保留规律,确定最佳色谱条件为:流速1.0 mL/min、柱温30℃,以1.0 mmol/L庚烷磺酸钠水溶液(pH 4.0)-乙腈为淋洗液进行梯度洗脱。在此条件下,4种吡啶阳离子和5种咪唑阳离子在15 min内达到基线分离。检出限(S/N=3)为0.31～0.54 mg/L,峰面积的相对标准偏差为0.10%～0.75%。将该方法用于实验室合成的离子液体样品分析,加标回收率为94%～98%。该方法准确、可靠,具有较好的实用性。     

反相硅胶整体柱离子对色谱法快速测定吡啶离子液体阳离子

建立了整体柱离子对色谱-紫外检测法梯度淋洗快速分离测定4种吡啶离子液体阳离子的方法。分离采用C18反相硅胶整体柱,以离子对试剂(用柠檬酸调节pH值)-乙腈为淋洗液,并采用多级梯度洗脱程序。实验考察了色谱柱、离子对试剂、乙腈浓度、色谱柱温度及流速对吡啶阳离子保留的影响,并讨论了其保留规律。咪唑阳离子的保留符合碳数规律。最佳色谱条件是:在流速3.0 mL/min,柱温30℃下,以1.0 mmol/L庚烷磺酸钠(pH 4.0)(A)+乙腈(B)为淋洗液进行梯度洗脱。淋洗梯度为0～2.0 min,10%B;2.0～2.5 min,10%～15%B;2.5～4.0 min,15%B;4.0～4.5 min,15%～20%B;4.5～10.0 min,20%B。在此条件下,4种吡啶阳离子可在7 min内基线分离。所测阳离子的检出限(S/N=3)为0.05～0.17 mg/L;峰面积的相对标准偏差(n=5)小于0.6%。将本方法用于实验室合成的离子液体样品和污水样品的分析,加标回收率在95.7%～99.0%之间。本方法准确、快速,具有较好的实用性。     

离子色谱-紫外检测法分离测定吡啶离子液体阳离子

建立了用离子色谱-紫外检测法分离测定3种吡啶离子液体阳离子(N-乙基吡啶、N-丁基吡啶和N-丁基四甲基吡啶)的方法。采用磺酸型阳离子交换柱,以乙二胺-柠檬酸-乙腈为流动相,考察了流动相和色谱柱温度对离子保留的影响,探讨了保留规律。实验发现,吡啶阳离子的保留过程是放热过程。优化的色谱条件为：流动相是0.2 mmol//L乙二胺-0.3 mmol//L柠檬酸-0.5%(v/v)乙腈(pH 4.2),流速1.0 mL/min,柱温30℃。在此条件下可以基线分离3种吡啶阳离子。所测阳离子的检出限(S/N=3)分别为0.01、0.01、0.02 mg/L,峰面积的相对标准偏差(n=5)小于0.8%。将此方法应用于分析实验室合成的吡啶离子液体样品,加标回收率在96.3%～103.7%之间。本方法准确、可靠、快速,具有较好的实用性。     

整体柱离子对色谱-间接紫外检测法快速分析吡咯烷离子液体阳离子

建立了快速分析无紫外光吸收的吡咯烷离子液体阳离子的离子对色谱-间接紫外检测法。采用反相硅胶整体柱,以(背景紫外吸收试剂-离子对试剂)水溶液-有机溶剂为流动相,分别讨论了背景紫外吸收试剂、检测波长、离子对试剂、有机溶剂、柱温及流速对分离测定吡咯烷阳离子的影响。最佳色谱条件为:以80%(V/V)(0.5 mmol/L对氨基苯酚盐酸盐-0.1 mmol/L庚烷磺酸钠)水溶液-20%(V/V)甲醇为流动相,检测波长230 nm,柱温30℃,流速2.0 mL/min。在此条件下,N-甲基,乙基吡咯烷阳离子、N-甲基,丙基吡咯烷阳离子和N-甲基,丁基吡咯烷阳离子在1.6 min之内基线分离,检出限(S/N=3)分别为0.02,0.03和0.07 mg/L,相对标准偏差(n=5)小于0.4%。将此方法用于分析实验室合成的离子液体样品,加标回收率在97.4%～98.0%之间。本方法快速、简单、准确、可靠,具有良好的实用性。     

反相离子对色谱-直接电导检测法分析六氟磷酸根离子液体阴离子

建立了反相离子对色谱-直接电导检测六氟磷酸根(PF6-)离子液体阴离子的分析方法。用DiamonsilC18反相色谱柱为分离柱,以离子对试剂-柠檬酸-乙腈混合水溶液为流动相,考察了离子对试剂、乙腈含量、pH值及色谱柱温度对六氟磷酸根保留的影响,并讨论了相关保留机理。在优化的色谱条件下,即流动相为0.05 mmol/L氢氧化四丁铵-0.038 mmol/L柠檬酸-35%乙腈(pH 5.5),流速1.0 mL/min,色谱柱温度40℃时,PF6-与其它常见阴离子(F-、Cl-、Br-、NO3-、SO24-、BF4-)达到基线分离且保留时间在15 min内。方法检出限(S/N=3)为0.25 mg/L,标准曲线的线性范围为0.5～100.0 mg/L,峰面积和保留时间的相对标准偏差(n=5)分别为0.17%和0.15%。该法用于1-丁基-3-甲基咪唑六氟磷酸盐和1-丙基-2,3-二甲基咪唑六氟磷酸盐两种离子液体中PF6-的测定,加标回收率分别为99%和104%。该方法简单、准确、可靠,实用性好。     

离子液体中卤素离子杂质的离子色谱-直接电导检测法分析

研究了离子色谱-直接电导检测法分离测定离子液体中的卤素离子(F~-、Cl~-、Br~-)杂质.采用Shim-pack IC-A3阴离子交换色谱柱,考察了淋洗液种类及浓度、流速和色谱柱温度对分离测定的影响.最佳色谱条件为:以1.25 mmol/L邻苯二甲酸氢钾为淋洗液,流速1.5 mL/min,色谱柱温45 ℃.在此条件下可以基线分离卤素离子,且NO~-_3、BF~-_4、SO~(2-)_4不干扰测定.该法测定卤素离子的检出限(S/N=3)为0.02 ～0.11 mg/L,峰面积的相对标准偏差(n=5)不大于0.7%,F~-、Cl~- 和Br~- 的标准曲线的线性范围分别为0.1 ～50、0.1 ～50、0.5 ～100 mg/L.将方法用于烷基咪唑四氟硼酸盐离子液体中卤素离子杂质的测定,加标回收率为98% ～102%.     

离子色谱-直接电导检测法分离测定吗啉离子液体阳离子

建立了离子色谱-直接电导检测法分析N-甲基乙基吗啉([MEMo]+)、N-甲基丙基吗啉([MPMo]+)2种吗啉离子液体阳离子的方法。采用磺酸型阳离子交换色谱柱,以乙二胺-乙腈为流动相,研究了色谱柱、流动相、色谱柱温度对吗啉阳离子保留的影响,并讨论了保留规律。结果表明,吗啉阳离子的保留基本属于离子交换模式,是一个放热过程。在柱温30℃,流速1.0 mL/min,以0.1 mmol/L乙二胺-0.5%乙腈(用盐酸调节至pH 5.0)为流动相条件下,[MEMo]+和[MPMo]+阳离子可在4 min内得到基线分离,检出限(S/N=3)分别为0.08、0.13 mg/L,峰面积的相对标准偏差(RSD,n=5)不大于1.5%。将此方法用于测定实验室合成的吗啉离子液体样品,加标回收率为94.0%～106.0%。方法准确、可靠、快速,具有较好的实用性,可满足离子液体样品的检测要求。     

同系物季铵盐离子液体阳离子的离子交换色谱法分析

建立了离子交换色谱-直接电导检测法分离测定3种同系物季铵盐离子液体阳离子(四甲基铵、四乙基铵和四丙基铵阳离子)的方法。采用磺酸型阳离子交换色谱柱,以乙二胺-柠檬酸-乙腈为淋洗液,考察了淋洗液种类、浓度及色谱柱温度对3种阳离子保留的影响。并根据测定对象不同,调整乙二胺浓度及乙腈含量以改善分离效果。淋洗液中增加乙腈含量,可明显缩短四丙基铵阳离子的保留时间,并改善其色谱峰形。季铵阳离子同系物的保留符合碳数规律。优化的色谱条件为:流速1.0 mL/min,色谱柱温度40℃;以0.02 mmol/L乙二胺-0.12 mmol/L柠檬酸(pH 4.0)为淋洗液分离测定四甲基铵;以0.2 mmol/L乙二胺-0.4 mmol/L柠檬酸-1%乙腈(pH 4.0)为淋洗液分离测定四乙基铵和四丙基铵。所测阳离子的检出限(S/N=3)分别为0.015,0.22,1.88 mg/L,相对标准偏差(n=5)均小于2.3%。将方法应用于表面活性剂和实验室合成的离子液体的分析,加标回收率为99%~104%。本方法简单、准确、可靠,具有良好的实用性。     

离子交换色谱分离-紫外检测法测定吡啶离子液体阳离子

建立了用离子交换色谱分离-紫外检测法测定N-乙基吡啶、N-丁基吡啶和N-丁基四甲基吡啶3种吡啶离子液体阳离子的方法。采用磺酸型阳离子交换柱,以乙二胺-柠檬酸-乙腈为流动相,研究了流动相和色谱柱温度对离子保留行为的影响和规律。实验发现,吡啶阳离子的保留过程是放热过程。优化后的色谱条件:流动相为乙二胺(0.2 mmol//L)-柠檬酸(0.3 mmol//L)-乙腈(0.5%,v/v,pH=4.2),流动相流速为1.0mL/min,色谱柱为Shim-pack IC-C1阳离子交换柱,色谱柱温度为30℃。在此条件下3种吡啶阳离子可以达到基线分离。所测阳离子的检出限(S/N=3)分别为0.01、0.01、0.02mg/L,峰面积的相对标准偏差(n=5)小于0.8%。紫外检测法测定化学实验室合成的吡啶离子液体样品,样品加标后测得的加标回收率在96.3%~104%。方法准确、可靠、快速,具有较好的实用价值。     

离子对色谱-间接紫外检测法分析哌啶离子液体阳离子

建立了快速分析无紫外光吸收的哌啶离子液体阳离子的离子对色谱-间接紫外检测法。采用反相C18色谱柱,以背景紫外吸收试剂-离子对试剂水溶液/有机溶剂为流动相分离哌啶离子液体阳离子。研究了背景紫外吸收试剂、检测波长、离子对试剂、有机溶剂、柱温、流速对分离测定哌啶阳离子的影响。最佳色谱条件为：以0.5 mmol/L对氨基苯酚盐酸盐-0.1 mmol/L庚烷磺酸钠水溶液/甲醇（80：20,v/v）为流动相,检测波长210 nm,柱温30 ℃,流速1.0 mL/min。在此条件下,3种哌啶阳离子可在4 min之内基线分离。所测阳离子的检出限（S/N=3）为0.137~0.545 mg/L,峰面积和保留时间的相对标准偏差（n=5）分别不高于0.72%和0.37%。将此方法用于分析实验室合成的哌啶类离子液体,加标回收率为97.0%~98.4%。本方法简便、快速,重现性、线性关系等均能满足哌啶类离子液体阳离子的定量分析要求。     

Rapid and simultaneous determination of imidazolium and pyridinium ionic liquid cations by ion-pair chromatography using a monolithic column

A method for rapid and simultaneous determination of imidazolium and pyridinium ionic liquid cations by ion-pair chromatography with ultraviolet detection was developed.Chromatographic separations were performed on a reversed-phase silica-based monolithic column using 1-heptanesulfonic acid sodium-acetonitrile as mobile phase.The effects of ion-pair reagent and acetonitrile concentration on retention of the cations were investigated.The retention times of the cations accord with carbon number rule.The method has been successfully applied to the determination of four ionic liquids synthesized by organic chemistry laboratory.     

Determination of Imidazolium Ionic Liquid Cations by Ion-Pair Chromatography Using a Monolithic Column and Direct Conductivity Detection

Determination of four imidazolium ionic liquid cations by ion-pair chromatography was carried out using direct conductivity detection. Chromatographic separations were performed on a silica-based monolithic column with 1-heptanesulfonic acid sodium + acetonitrile + citric acid as eluent. Carbon number rule and influence of acetonitrile on the retention of imidazolium cations were discussed. Detection limits (S/N = 3) for the cations were 2.1–55.9 mg L^?1. Relative standard deviations (RSD, n = 5) for peak areas were less than 3.0%. The method has been successfully applied to the determination of two ionic liquids synthesized by organic chemistry lab.     

Rapid and simultaneous determination of piperidinium and pyrrolidinium ionic liquid cations by ion pair chromatography coupled with direct conductivity detection

A method of ion-pair chromatography with direct conductivity detection was developed on a silicabased monolithic column for the fast and simultaneous determination of piperidinium and pyrrolidinium ionic liquid cations. The effects of the mobile phase, column temperature and flow rate on the retention of the cations were investigated. The retention rules were discussed. As an ion-pair reagent, sodium heptanesulfonate is more suitable than sodium pentanesulfonate for the separation and determination of piperidinium and pyrrolidinium cations. The increase of ion-pair reagent concentration led to the increased retention time of the cations. When acetonitrile content and mobile phase flow were increased, the retention time of the cations became shorter. The retention of piperidinium and pyrrolidinium cations is an exothermic process, and the retention of the cations conforms to the carbon number rule. The chromatographic analysis was performed using the Chromolith Speed ROD RP-18e column, 0.5 μmol/L sodium heptanesulfonate-5% acetonitrile as the mobile phase at a flow rate of 3.0 mL/min and column temperature of 30℃. Separation of N-methyl-N-ethyl piperidinium, N-methyl-N-propyl piperidinium, N-methyl-N-butyl piperidinium and N-methyl-N-ethyl pyrrolidinium, N-methyl-N-propyl pyrrolidinium, N-methyl-N-butyl pyrrolidinium cations were achieved within 10 min. The detection limits (S/N=3) were between 0.19 and 3.08 mg/L. Relative standard deviations (n=5) for peak areas were less than 1.2%. The method has been applied to the determination of piperidinium and pyrrolidinium cations in ionic liquid samples. The spiked recoveries of ionic liquid cations were between 96% and 111%. The method is accurate, reliable, rapid, and has a better practicability.     

整体柱离子对色谱-间接紫外检测法快速测定N-甲基,丙基吗啉阳离子

建立了快速分析无紫外吸收的N-甲基,丙基吗啉阳离子的离子对色谱-间接紫外检测法。采用反相C18硅胶整体柱,以背景紫外吸收试剂-离子对试剂-有机溶剂为流动相。研究了背景紫外吸收试剂、检测波长、离子对试剂、有机溶剂、柱温、流速对吗啉阳离子测定的影响。最佳色谱条件为:(0.5 mmol/L对氨基苯酚盐酸盐-0.1 mmol/L庚烷磺酸钠)溶液-甲醇(9:1, v/v)为流动相,检测波长230 nm,柱温30 ℃,流速1.0 mL/min。在此条件下,N-甲基,丙基吗啉阳离子的保留时间为2.966 min,检出限为0.07 mg/L(S/N=3),峰面积的相对标准偏差为2.1%(n=5),保留时间的相对标准偏差为0.02%(n=5)。将此方法用于分析实验室合成的N-甲基,丙基吗啉离子液体,加标回收率为98.8%。结果表明本方法简便、快速。     

离子色谱-直接电导检测法分析哌啶离子液体阳离子

建立了离子色谱-直接电导检测法分析N-甲基,乙基哌啶(［MEPi］+)、N-甲基,丙基哌啶(［MPPi］+)和N-甲基,丁基哌啶(［MBPi］+) 3种哌啶离子液体阳离子的方法。采用磺酸型阳离子交换色谱柱,以乙二胺-柠檬酸-乙腈为流动相。考察了流动相组成及色谱柱温度对哌啶阳离子保留的影响,并讨论了保留规律。结果表明,哌啶阳离子的保留是一个放热过程,即哌啶阳离子的保留时间随着色谱柱温度的升高而缩短,且哌啶阳离子同系物的保留符合碳数规律。在以0.2 mmol/L乙二胺-0.3 mmol/L柠檬酸-3%(v/v)乙腈(pH 4.4)为流动相、流速1.0 mL/min、柱温30 ℃条件下,［MEPi］+、［MPPi］+和［MBPi］+3种哌啶阳离子可以在7 min内分离,检出限(信噪比为3)分别为0.14、0.20和0.56 mg/L,峰面积的相对标准偏差(n=5)在1.2%以下。将此方法应用于分析实验室合成的哌啶离子液体样品,加标回收率在97.6%与105.1%之间。本方法准确、可靠、快速,具有较好的实用性。     

A Simple Method for Determination of Homologue Imidazolium Cations in Ionic Liquids Using IC with Direct Conductivity Detection

An investigation was carried out into the fast determination of five homologue imidazolium cations in ionic liquids by ion chromatography using a cation-exchange column and direct conductivity detection. Ethylenediamine, complex organic acid (citric acid, oxalic acid and tartaric acid) and organic modifiers (acetonitrile) were used as mobile phase. The influences of the eluent types, eluent concentration, eluent pH and column temperature on separation of the cations were discussed. Simultaneous separation and determination of the five homologue imidazolium cations in ionic liquids were achieved under an optimum condition. The optimized mobile phase was consisted of 0.25 mmol L^?1 ethylenediamine + 0.5 mmol L^?1 citric acid + 3% acetonitrile (v/v) (pH 4.1), set at a flow rate of 1.0 mL min^?1. The column temperature was 40 °C and detection limits were obtained in the range of 1.1–45.6 mg L^?1. The relative standard deviations of the chromatographic peak areas for the cations were <3.0% (n = 5). This method was successfully applied to separate imidazolium cations in ionic liquids produced by organic synthesis. The recoveries of spiked components were 92.5–101.9%.     

Analysis of Morpholinium Ionic Liquid Cations by Hydrophilic Interaction Columns Coupled with Indirect UV Detection

A method was developed for the separation and detection of morpholinium ionic liquid cations by hydrophilic interaction column combined with indirect ultraviolet detection using imidazolium ionic liquids as ultraviolet absorbents in high‐performance liquid chromatography. The effects of the ultraviolet absorbents, organic solvents, and the pH value of the aqueous solution in the mobile phase for the determination of morpholinium cations were investigated by using a hydrophilic column with carbamoyl group as the analytical column. The retention and detection behavior of morpholinium cations was discussed. The suitable chromatographic conditions were 0.8 mmol/L 1‐ethyl‐3‐methyl‐imidazolium tetrafluoroborate aqueous solution (pH 3.5 adjusted with acetic acid)/acetonitrile (45/55, v/v) as the mobile phase and a detection wavelength of 210 nm. Under these conditions, the baseline separation of N‐methyl‐N‐ethyl‐morpholinium cation ([MEMo]⁺) and N‐methyl‐N‐propyl‐morpholinium cation ([MPMo]⁺) was successfully achieved in 15 min. The detection limits of [MEMo]⁺ and [MPMo]⁺ were 0.595 and 0.531 mg/L, respectively. Relative standard deviations were less than 0.2%. This method has been successfully applied to the analysis of morpholinium ionic liquid samples synthesized in chemical laboratories, which is simple, reliable, and practical.