硼掺杂金刚石薄膜电极上二氯酚的电化学阻抗谱研究

以2,4-二氯酚(2,4-DCP)和2,6-二氯酚(2,6-DCP)为模型污染物,采用循环伏安法和电化学阻抗谱研究了硼掺杂金刚石(BDD)电极上2种氯酚的电催化氧化过程.结果表明,2,4-DCP和2,6-DCP的氧化电位分别为1.55和1.62 V.等效电路拟合结果表明,当极化电位由开路电位提高至1.5 V时,2种氯酚的电荷转移电阻均有明显下降,反应控制步骤为扩散控制步骤.与2,6-DCP相比,2,4-DCP在BDD电极上更容易发生直接电化学氧化.     

离子液体液-液萃取-高效液相色谱测定水中酚类化合物

建立了离子液体1-丁基-3-甲基咪唑六氟磷酸盐([C4mim][PF6])液-液萃取-高效液相色谱测定水中酚类化合物的方法.研究了水相pH值、萃取时间、水相体积及盐的浓度对萃取的影响.最佳萃取条件分别为:水相pH值为5,萃取时间为40 min,水相体积为60 mL.对比了离子液体对1-辛醇对苯酚、4-硝基苯酚、2-硝基苯酚、2,4-二甲基苯酚和双酚A的富集效率.在最佳条件下,离子液体对5种酚的富集倍率在9～151之间,方法对苯酚、4-硝基苯酚、2-硝基苯酚、2,4-二甲基苯酚和双酚A的检出限分别为:2.0、0.9、0.3、1.8和1.1 μg/L.将该方法应用于自来水、河水、湖水和污水的检测,回收率为87.9%～109.9%.     

液下单液滴微萃取-高效液相色谱法测定二氯酚

采用液下单液滴微萃取样品处理方法富集水中的2,4-二氯酚和2,6-二氯酚,高效液相色谱法测定.考察了不同萃取剂、萃取条件及测定条件对检测结果的影响.2,4-二氯酚和2,6-二氯酚的线性范围分别在0.001～20 mg/L和0.003～20 mg/L之间,检出限分别为0.001和0.003 mg/L.     

液相色谱法测定地表水中氯酚类化合物

采用单滴液相微萃取-高效液相色谱法测定水中的4-氯酚、2,6-二氯酚、2,4-二氯酚和2,4,6-三氯酚。色谱条件为:Diamonsil C18柱(250×4.6mm i.d.,5μm),柱温:室温,流速1.0mL/min,以甲醇∶水∶甲酸(体积比70∶30∶0.2)为流动相,225nm紫外检测。考察了萃取溶剂种类、萃取时间、萃取温度、搅拌速度和pH值对萃取效率的影响。4-氯酚、2,6-二氯酚、2,4-二氯酚在1.5~100mg/L和2,4,6-三氯酚在2.5~100mg/L范围内有良好线性,相关系数不低于0.9996,回收率在74.9%~84.4%之间,相对标准偏差低于4.9%。     

可忽略损耗液相微萃取法同时测定辛醇-水分配系数和电离常数

以4-氯酚(4-CP)、2,4-二氯酚(2,4-DCP)和2,4,6-三氯酚(2,4,6-TCP)为模型化合物,建立了中空纤维膜支载-可忽略损耗液相微萃取法(HF-nd-LPME)和高效液相色谱(HPLC)联用,同时测定辛醇-水分配系数(Kow)和电离常数(pKa)的方法。在60 mL正辛醇饱和的样品溶液(1mmol/L NaH2PO4,2μg/mL4-CP、2,4-DCP和2,4,6-TCP)中放入2个支载有0.16μL正辛醇的中空纤维膜萃取装置,静置96 h确保达到萃取平衡。然后将萃取装置取出并用甲醇解吸,经HPLC测定得到萃取到正辛醇中的目标物浓度coctanol。coctanol与样品中目标物原始浓度cwater的比值即为Kow。通过测定模型化合物在不同pH3.0~13条件下的Kow值,并依据化合物的Kow、pKa与pH的关系模型进行非线性拟合,即可计算得出模型化合物pKa值。实验表明,本方法测定的三种模型化合物的Kow和pKa值与文献报道值一致。     

土壤中不同极性污染物的亚临界水选择性萃取

研究了用亚临界水萃取技术选择性萃取土壤中3种不同极性的污染物:2,4-二氯酚(2,4-DCP)、4-氯联苯(4-PCB)和六氯苯(HCB)。研究了在不同温度下亚临界水对分析物的萃取效率。125℃时,萃取物主要是2,4-DCP;250℃时,主要萃取4-PCB和HCB。同时,研究了亚临界水萃取时间、萃取体积对3种物质的萃取效率的影响,确定了土壤中HCB的最佳亚临界水萃取条件为萃取水体积4mL,萃取时间75m in,萃取温度250℃。本方法用于实际样品中的HCB萃取,通过改变萃取温度,可以去除其它污染物对HCB测定的影响,测定结果与索氏提取-GC分析结果吻合较好。与USEPA标准方法8081A相比,本方法可以显著缩短萃取时间、简化净化步骤及减少有机试剂的用量。     

醇与离子液体二元双水相体系萃取盐酸多西环素

基于小分子醇双水相体系和离子液体双水相体系,建立了正丙醇与亲水性离子液体1-丁基-3-甲基咪唑四氟硼酸[Bmim]BF4和(NH4)2SO4形成的二元双水相体系萃取盐酸多西环素的新方法。考察了(NH4)2SO4含量、正丙醇用量、pH值、离子液体含量以及盐酸多西环素含量对盐酸多西环素分配行为的影响。结果表明:当醇和离子液体二元双水相体系的pH值在4.0～5.0范围内,(NH4)2SO4含量为34%,且盐酸多西环素的质量浓度在25～95 mg/L之间时,该体系对盐酸多西环素的萃取率可达90.26%～95.71%,分配系数可达62.452～149.401。     

分子印迹聚合物纤维固相微萃取-高效液相色谱法测定水中痕量2,4-二氯苯酚

利用分子印迹固相微萃取-高效液相色谱法测定了水中痕量的2,4-二氯苯酚(2,4-DCP)。在石英毛细管中,以2,4-DCP为模板分子,甲基丙烯酸(MAA)为功能单体,聚合反应合成了2,4-DCP分子印迹聚合物纤维,考察模板分子的浓度,功能单体与交联剂的比例,聚合反应时间对制备分子印迹聚合物纤维的影响,优化了2,4-DCP的吸附时间对分子印迹聚合物纤维萃取效率的影响。高效液相色谱法测定了萃取后标准样品溶液中2,4-DCP的含量萃取率大于80%,方法的线性范围为10~120μg/L,检出限为2.5μg/L,相关系数(R2)在0.9993~0.9995之间,实测了自来水、湖水和工业废水水样,加标回收率为91.4%~106.0%,相对标准偏差为1.4%~6.6%。     

聚邻氨基苯硫酚/纳米金复合膜分子印迹传感器测定2, 4-二氯苯酚

在2,4-二氯苯酚(2,4-DCP)存在下, 在金电极表面自组装邻氨基苯硫酚(oATP)并电聚合oATP/金纳米粒子, 制得2,4-DCP印迹复合膜电化学传感器.采用循环伏安法和交流阻抗技术对传感器制备过程进行了表征, 以K₃Fe(CN)₆为探针, 间接对2,4-DCP进行定量分析.结果表明, 2,4-DCP在5.0×10^-8~1.2×10^-4 mol/L 浓度范围内与K₃Fe(CN)₆示差脉冲伏安曲线的峰电流呈线性关系(R²=0.9964), 检出限为1.5×10^-8 mol/L(S/N=3).该印迹传感器可在几种氯代酚干扰下选择性测定2,4-DCP.利用该传感器对环境水样进行加标回收检测, 回收率为95.2%~109.3%.     

纳米Fe0降解2,4-二氯酚的影响因素及其机理

采用化学还原法制备了纳米Fe⁰, 并研究了不同条件下纳米Fe⁰对2,4-二氯酚(2,4-DCP)的降解情况, 探讨了纳米Fe⁰降解2,4-二氯酚的反应途径. 结果表明, 纳米Fe⁰对2,4-二氯酚的去除作用包括吸附、脱氯、开环三种机制. 其中脱氯作用是一种界面反应, 发生在氯酚分子被吸附到Fe原子表面之后. 2,4-二氯酚可以脱去一个氯原子生成2-氯酚或4-氯酚, 也可以脱去两个氯原子生成苯酚. 随着氯酚初始浓度的增大, 其相对去除率略有降低, 但绝对降解量有较大提高. 温度不仅影响脱氯速率, 而且影响氯酚的去除途径. 温度较高时脱氯作用占主导地位, 先脱氯后开环, 温度较低时吸附作用占主导地位, 较易发生先开环后脱氯的情况.     

Thermodynamic studies of partitioning behavior of cytochrome c in ionic liquid-based aqueous two-phase system

The ionic liquid/aqueous two-phase extraction systems (ATPSs) based on imidazolium ionic liquids were used to extract cytochrome c. Effects of the alkyl chain length of the ionic liquid cations, concentration of potassium citrate, temperature and pH on the extraction efficiency have been investigated. The thermodynamic parameters (ΔG(T)°, ΔH(T)° and ΔS(T)°) associated with Cyt-c partitioning in aqueous two phase systems were determined. Thermodynamic studies indicated that the partitioning of Cyt-c was driven by both hydrophobic and electrostatic interactions in the extraction process. Under the optimum conditions, experiment results showed that 94% of the cytochrome c could be extracted into the ionic liquid-rich phase in a one-step extraction. The structural characterization of Cyt-c in the IL ATPS was investigated by UV-vis and circular dichroism (CD) spectra. The results demonstrated that no direct bonding interaction observed between ionic liquid and cytochrome c, while the native properties of the cytochrome c were not altered. Compared with traditional liquid-liquid extractions based on toxic organic solvents, ionic liquid/aqueous two phase extraction offers clear advantages due to no use of volatile organic solvent and low consumption of imidazolium ionic liquids.     

Studies on Liquid/liquid Extraction of Copper Ion with Room Temperature Ionic Liquid

Room temperature ionic liquids are regarded as “Green solvents” for their nonvolatile and thermally stable properties. They are employed to replace traditional volatile organic solvents in organic synthesis, solvent extraction, and electrochemistry. In this work, a water immiscible room temperature ionic liquid, 1‐butyl‐3‐methylimidazolium hexafluorophosphate [C₄mim][PF₆], was used as an alternative solvent for liquid/liquid extraction of copper ions. Metal chelators, including dithizone, 8‐hydroxyquinoline, and 1‐(2‐pyridylazo)‐2‐naphthol, were employed to form neutral metal‐chelate complexes with copper ions so that copper ions were extracted from aqueous solution into [C₄mim][PF₆]. The parameters that affect the extraction of copper ions with this biphasic system were investigated. The extraction behavior in this novel biphasic system is shown to be consistent with that of traditional solvents. For example, the extraction with this biphasic system is strongly pH dependent. So, the extraction efficiency of coppers ion from an aqueous phase can be manipulated by tailoring the pH value of the extraction system. Hence, the extraction, separation and preconcentraction of copper ions can be accomplished by controlling the pH value of the extraction system. It appears that the use of ionic liquid as an alternate solvent system in liquid/liquid extraction of copper ions is very promising.     

离子液体双水相体系萃取分离牛血清白蛋白

建立了由亲水性离子液体四氟硼酸1-甲基-3-丁基咪唑([Bmim]BF4)和KH2PO4形成的双水相体系萃取分离牛血清白蛋白(BSA)的新方法。研究了不同盐及盐的浓度、离子液体浓度以及蛋白质用量、溶液酸度、其它共存物质对双水相成相及BSA萃取率的影响,结果表明,磷酸二氢钾盐浓度为80g/L,离子液体浓度在160~240mL/L,BSA的浓度为30~50mg/L,溶液酸度在pH4~8范围,离子液体双水相体系对BSA有较高的萃取率。用加入不同类型表面活性剂探讨了离子液体与蛋白质之间的作用。     

新型功能化离子液体的合成及液-液萃取钕(Ⅲ)的研究

研究了新型功能化离子液体1-戊基-3-(3-乙基苯基膦酰基)丙基咪唑双(三氟甲基磺酰基)亚胺盐的合成及对Nd(Ⅲ)的萃取性能,考察了水相酸度、萃取时间、杂质离子等对萃取性能的影响。结果表明,在0.13g该离子液体中,萃取时间为30min,5 mL pH 9.0的Nd(Ⅲ)溶液浓度在0.1～5.0μg/mL时,其线性回归方程为Y=-29352+2.423×106ρ(μg/mL),线性相关系数和最低检测限分别为0.9982和0.0025μg/mL。同时研究了离子液体的回收利用,在5%HNO3介质中洗脱30 min,Nd(Ⅲ)洗脱率达86%以上,回收后的离子液体可再利用。     

离子液体萃取阿魏酸和咖啡酸的性能研究

以1-甲基-3-丁基咪唑六氟磷酸盐([C4mim][PF6])和1-甲基-3-己基咪唑六氟磷酸盐([C6mim][PF6])离子液体为萃取剂,采用紫外分光光度法研究了溶液pH值、温度、相比率及盐的种类和浓度对其萃取阿魏酸和咖啡酸效率的影响,考察了被萃取物的回收及离子液体的循环使用,探讨了两种离子液体替代传统有机溶剂阿魏酸和咖啡酸的可能性。实验结果表明:萃取温度和无机盐的种类及浓度对FA和CA萃取效率的影响较小;水相pH值对萃取效率有较大的影响,萃取FA适宜pH应小于3.67,萃取CA适宜pH应小于3.71;被萃取物浓度增大,萃取效率降低,而相体积比增大其萃取效率升高;两种离子液体对FA和CA的萃取效率[C4mim][PF6]大于[C6mim][PF6],同种离子液体对FA的萃取效率大于CA;在萃取相中的FA和CA可定量回收,且被萃取物中离子液体的残留[C6mim][PF6]小于[C4mim][PF6],离子液体可循环使用。     

离子液体-超声波辅助萃取火焰原子吸收法测定油画棒中的可迁移微量Cd2+

以离子液体为萃取介质,超声波辅助萃取油画棒中的可迁移微量Cd2,以硝酸溶液反萃取后用火焰原子吸收法测定镉.考察了主要影响因素对萃取效果的影响.结果表明,以1-丁基-3-甲基咪唑六氟磷酸盐离子液体为萃取介质,溶液pH值为9.0、金属螯合剂用量为2.00 mL、离子液体的用量为2.00 mL、反萃剂为4.00 mL1.00...     

离子液体双水相溶剂浮选法分离/富集桑黄黄酮类成分

将亲水性离子液体氯化-1-丁基-3-甲基咪唑([C4mim]Cl)和K2HPO4形成的双水相体系与溶剂浮选结合,建立了分离/富集桑黄中总黄酮类成分的方法。考察了分相盐的种类和用量、样品量、溶液pH值、浮选时间和氮气流速对浮选效果的影响,并与双水相萃取进行比较。当浮选分相盐K2HPO4的质量浓度为50%、溶液pH=9.53、离子液体的用量为3 mL、浮选时间为50 min、氮气流速为30 mL/min时,浮选效率最佳,达到85.31%,富集倍数为8.59。离子液体双水相溶剂浮选法浮选效率高,富集倍数大,为中草药有效成分分离/富集提供了新方法。     

Application of sucrose fatty acid ester to reverse micellar extraction of lysozyme

Reverse micellar extraction of lysozyme has been carried out using an organic solution containing a mixture of monoester and polyester of sucrose fatty acid ester. The forward extraction of lysozyme from the feed aqueous phase to the reverse micellar organic phase of the mixture of monoester and polyester of sucrose fatty acid ester at pH 7.2 was strongly dependent upon the weight fraction of monoester, while any amount of lysozyme was not extracted only by using monoester or polyester. The forward extraction ratio dramatically increased with an increase in the concentration of fatty acid ester, and was high around neutral pH and at low ionic strength. The backward extraction of lysozyme from the reverse micellar organic phase to the recovery aqueous phase exhibited high efficiency at acidic pH value or at high ionic strength. The addition of sucrose into the recovery aqueous phase promoted the backward extraction ratio, and caused the activity of lysozyme recovered from the reverse micellar phase to be retained perfectly.     

Liquid-liquid extraction of lysozyme using a dye-modified ionic liquid

An affinity-dye, Cibacron Blue 3GA (CB), derivatized organic salt [BMIM]3[CB] was synthesized for lysozyme extraction. This compound was formed by mixing an ionic liquid (IL) [BMIM][Cl] and the silver salt of CB. Liquid-liquid extractions of lysozyme from the aqueous and [BMIM]3[CB] in [BMIM][PF6] solutions were examined in this study. The transfer of lysozyme from the aqueous phase to the IL phase decreased while the pH of the aqueous phase increased. An extraction higher than 90% was observed at pH 4. Under a high ionic strength, the lysozyme would transform back from the IL phase into the aqueous phase. Lysozyme molecules were almost quantitatively recovered from the IL phase to the aqueous solutions of 1M KCl under pH 9-11. It appeared that the extraction was specific for lysozyme in contrast to cytochrome c, ovalbumin, and bovine serum albumin. The extraction efficiency of the IL phase remained essentially the same after eight cycles of extraction.