负载十四烷基二甲基苄基铵的微晶三苯甲烷分离富集痕量Cu(Ⅱ)

在SCN-存在下,Cu(Ⅱ)与SCN-形成的Cu(SCN)42-可被吸附在负载氯化十四烷基苄基铵(Zeph)的微晶三苯甲烷(TPM)上。在最佳条件下,Cu(Ⅱ)能与常见阳离子Fe(Ⅲ)、Ni(Ⅱ)、Cr(Ⅲ)、Al(Ⅲ)、Mn(Ⅱ)、Pb(Ⅱ)、Cd(Ⅱ)等完全分离,且富集时基本不受SO24-、NO3-、SCN-、Br-、Cl-、ClO4-的影响。富集因子可达100倍,回收率在91%以上。该方法已成功用于环境水样中Cu(Ⅱ)的富集与测定。     

微晶酚酞-乙基紫分离富集镉(Ⅱ)

微晶酚酞-乙基紫分离富集镉(Ⅱ);微晶酚酞;乙基紫;分离富集;镉(Ⅱ)     

微晶蒽分离富集测定痕量铜(II)

建立了一种利用微晶蒽吸附分离富集环境水样中痕量Cu(Ⅱ)的新方法。 研究表明,pH=3.0时, Cu(Ⅱ)与1-(2-吡啶偶氮)-2-萘酚形成红棕色螯合物被微晶蒽定量吸附,而Pb(Ⅱ)、Mn(Ⅱ)、Co(Ⅱ)、Ni(Ⅱ)、Cd(Ⅱ)、Zn(Ⅱ)、Fe(Ⅲ)和Al(Ⅲ)等完全留在溶液中,从而实现Cu(Ⅱ)与它们的分离。 该方法可直接用于1 L水样中痕量Cu(Ⅱ)的分离与富集,富集倍数达200倍,回收率91.0%~104.0%, 最低检出限为0.026 μg/L;应用于不同水样中Cu(Ⅱ)的测定,结果令人满意。     

活性炭分离富集水体中痕量镉

建立了以PAN为吸附辅助剂,以活性碳为吸附剂,结合火焰原子吸收法测定地表水中痕量镉的方法.研制了以微量过滤器和医用注射器组成的分离富集装置;探讨了镉吸附解吸的最佳试验条件,并应用于实际环境水样中痕量镉的测定,回收率为98.25%～105.0%.该方法简化了分离富集程序,操作简单,迅速,能同时进行6～8个样品的分析测定,具备一定实用性.     

氨基羧酸纤维分离富集水中痕量铅镉

铅、镉是有毒元素,严重危害人体健康,因此水中铅镉的含量历来是水质监测评价中的必测项目。但由于水样中铅镉含量较低,且基体干扰严重,所以测定前必须采取一定的富集与分离方法。本文在原螯合纤维制备的基础上［１,２］改换某些原料［３,４］,制备了氨基乙酸纤维滤...     

阴离子交换树脂分离富集水中痕量镉

先用草酸处理水样中的镉离子,生成的[Cd(C2O4)2]2-络阴离子通过强碱性阴离子交换树脂分离富集,最后用火焰原子吸收分光光度法测定了水样中的痕量镉。该法简便,选择性好,富集倍数高,应用于实际水样的检测,回收率为98%~102%,结果令人满意。     

印迹壳聚糖/凹土分离富集-FAAS测定水中痕量镉

建立了用离子印迹壳聚糖/凹土(ⅡGA)分离富集-火焰原子吸收光谱(FAAS)测定痕量镉的新方法.在动态吸附条件下,系统地研究了溶液pH值、流速、洗脱条件和干扰离子对痕量镉分离富集的影响;在pH4.5、上样流速为0.60 mL/min的条件下,镉能被ⅡCA定量富集;吸附的镉可用1.0 mol/L HCl-0.1 mol/...     

微晶酚酞预富集-分光光度法测定痕量Co(Ⅱ)

建立了一种以微晶酚酞作为固态吸附剂对样品中痕量的Co（Ⅱ）分离富集的新方法,富集后的co（Ⅱ）可直接用光度法测定。控制一定条件,Co（Ⅱ）能与常见阳离子Ni（Ⅱ）、Cd（Ⅱ）、Al（Ⅲ）、Ca（Ⅱ）、Mg（Ⅱ）、Pb（Ⅱ）、Mn（Ⅱ）、Fe（Ⅲ）、Bi（Ⅲ）等完全分离,且富集时基本不受SO4^2-、NO3^-、Br^-、Cl^-、I^-等阴离子影响。微晶酚酞对Co（Ⅱ）的吸附容量为23．5mg／g;富集因数可达200倍,回收率在97．6％以上,RSD为1．1％～2．3％。已用于环境水样及日常用水中Co（Ⅱ）的富集测定。     

水中痕量镉的准液膜富集

准液膜法是在液膜法基础上提出的新分离方法，它保持了液膜法分离富集的高效能，但省去了液膜法的制乳与破乳过程，使操作更为简便易行。本文用此法富集了水及废水中痕量镉，富集倍数可达２３０倍，镉的回收率在９７％以上。     

巯基葡聚糖凝胶分离富集光度法测定镉的研究

研究了在ＴｒｉｔｏｎＸ－１００存在下，新显色剂邻羧基苯基重氮氨基偶氮苯（ＣＤＡＡ）与镉的显色体系，在ｐＨ１０．６的Ｎａ２Ｂ４Ｏ７－ＮａＯＨ体系中，显色反应灵敏度很高。络合物的最大吸收位于５４５ｎｍ处，其摩尔吸光系数为２．２２×１０＾５Ｌ·ｍｏｌ＾－１·ｃｍ＾－１。镉含量在０￣１２μｇ／２５ｍＬ符合比耳定律。将该体系用于巯基葡聚糖凝胶分离富集－光度法测水样中微量镉，结果令人满意。     

Study on Preconcentration of Trace Copper Using Microcrystalline Triphenylmethane Loaded with Malachite Green

The paper describes a novel method for copper preconcentration using microcrystalline triphenylmethane loaded with malachite green prior to the determination by the flame atomic absorption spectrometry （FAAS）. Under the optimum conditions, Cu（Ⅱ） can be totally adsorbed on the surface of microcrystalline triphenylmethane, and completely separated from Pb（Ⅱ）, Cd（Ⅱ）, Co（Ⅱ）, Cr（Ⅲ）, Ni（Ⅱ）, Mn（Ⅱ）, Fe（Ⅲ） and Al（Ⅲ） by controlling acidity. The preconcentration factor of this proposed method is 200. The recovery is in a range of 97.5%-105%. The relative standard deviation （RSD） is not beyond 3.0%. The proposed method has been successfully applied to the determination of trace copper in various water samples with satisfactory results.     

Study on Determination of Trace Copper by Spectrophotometry after Flotation Separation Using Microcrystalline Adsorption System

The paper presents a novel method for the flotation separation of Cu²⁺ using microcrystalline adsorption system prior to the determination by spectrophotometry. The effects of different parameters, such as the dosages of NH₄SCN and octadecyl trimethyl ammonium bromide (OTMAB), various salts on the flotation yield of Cu2+ have been investigated to select the optimum experimental conditions. The possible flotation separation mechanism of Cu²⁺ was discussed. The results showed that under the optimum conditions, octadecyl trimethyl ammonium bromide cation (OTMAB⁺) reacted with SCN^‐ to produce the microcrystalline matter (Ms‐M) of (OTMAB⁺·SCN^‐), the water‐insoluble ternary association complex of [Cu(SCN)₄] (OTMAB)₂ which produced by Cu²⁺ and SCN^‐, OTMAB⁺ was quantificationally adsorbed on the surface of Ms‐M of (OTMAB²⁺·SCN^‐) and was floated above water phase, the liquid‐solid phases were formed with clear interface. In this condition, K⁺, Na⁺, Ca²⁺, Mg²⁺, Al³⁺, Fe²⁺, Mn²⁺, Ni²⁺, Cd²⁺ and Co²⁺ could not be floated. Therefore, Cu²⁺ was separated completely from the above metal ions. A new method of determination of trace copper by flotation separation was established. The proposed method has been successfully applied to the determination of Cu²⁺ in plating waster water, and the results agreed well with AAS method. The recoveries were 93.3%～107.8%, and the RSD was 1.9%～2.1%.     

Separation and preconcentration

Summary A general review is given on separation and pre-concentration methods. Among the various procedures especially chromatography and ion-exchange for separation, and absorption and extraction for preconcentration are discussed in detail.

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Trennung und Anreicherung

Zusammenfassung Ein allgemeiner Überblick wird gegeben, wobei zur Trennung besonders chromatographische und Ionenaustausch-Methoden, zur Anreicherung Absorptions- und Extraktionsverfahren ausführlicher diskutiert werden.

Lecture presented at Euroanalysis I Conference, 28. 8.–1. 9. 1972 in Heidelberg, Germany.     

Separation/preconcentration and determination of cadmium ions by solidification of floating organic drop microextraction and FI-AAS

A simple and selective method for the separation and preconcentration of cadmium in water samples based on solidified floating organic drop microextraction (SFODME) was developed. The cadmium ion in aqueous solution was converted to CdI₄²⁻ and was then extracted with 160 μL of 1-undecanol containing cationic surfactant of methyltrioctylammonium chloride (0.2 mol/L). When the extraction was completed, the sample vial was cooled in an ice bath for 5 min. The solidified extract was transferred into a conical vial where it melted immediately. It was then diluted to 250 μL upon addition of ethanol, and 100 μL of it was analyzed by flow injection flame atomic absorption spectrometry (FI-FAAS).Factors that influence the extraction and ion pair formation, such as pH, concentration of iodide and methyltrioctylammonium chloride, extraction time, sample volume, and ionic strength were optimized. Under the optimized conditions, a preconcentration factor of 640, detection limit of 0.0079 μg/L and good relative standard deviation of ±5.4% at 5 μg/L were obtained. The procedure was applied to tap water, well water, and sea water; and accuracy was assessed through recovery experiment and independent analysis by graphite atomic absorption spectrometry. The accuracy was also evaluated through analyses of certified reference ore.     

Study on Determination of Trace Nickel in Water Samples after Separation/enrichment using Microcrystalline Phenolphthalein Loaded with Chelate

The paper presents a novel method for the separation/enrichment of trace Ni²⁺ using microcrystalline phenolphthalein loaded with chelate prior to the determination by spectrophotometry. The effects of different parameters, such as the dosages of phenolphthalein and sodium diethyldithiocarbamate (DDTC), various salts and acidity on the enrichment yield of Ni²⁺ have been investigated to select the experimental conditions. The possible enrichment mechanism of Ni²⁺ was discussed. The results showed that under the optimum conditions, Ni²⁺ could be quantificationally adsorbed on the surface of microcrystalline phenolphthalein in the form of the chelate precipitate of Ni(DDTC)₂, while K⁺, Na⁺, Ca²⁺, Mg²⁺, Zn²⁺, Fe²⁺, Al²⁺, Pb²⁺ and Cd²⁺ could not be adsorbed at all. Therefore, Ni²⁺ was completely separated from the above metal ions in the solution. A new method for the separation/enrichment and determination of trace nickel using microcrystalline phenolphthalein loaded with chelate was established. The proposed method has been successfully applied to the determination of Ni²⁺ in various water samples, and the results agreed well with those obtained by FAAS method.     

Cadmium Preconcentration from Aqueous Environmental Samples Using Microcrystalline Phenolphthalein Modified by Crystal Violet

Abstract

The present work describes a novel method for cadmium preconcentration and separation with microcrystalline phenolphthalein. Phenolphthalein as an extractant modified by crystal violet was originally applied to cadmium extraction from aqueous solution. Cadmium(II) as CdI₃ ^? and CdI₄ ^2? can associate with the cationic crystal violet (CV⁺) forming water‐insoluble ion‐association complexes (CdI₃ ^?) · (CV⁺) and (CdI₄ ^2?) · (CV⁺)₂, which are quantitatively adsorbed on microcrystalline phenolphthalein over the pH range from 1.0 to 6.0. All experimental parameters necessary for successful preconcentration and separation have been investigated and optimized. The study shows that common metal ions, such as Zn(II), Fe(II), Co(II), Ni(II), Mn(II), Cr(III) and Al(III), cannot interfere with cadmium extraction in this microcrystalline system by controlling acidity. The extraction can be accomplished in 15 min. The interaction between CdI₃ ^?and CdI₄ ^2? and CV⁺ plays an important role in the extraction process. The reported method was successfully applied to the preconcentration and separation of cadmium in synthetic samples and real samples with satisfactory results. The results proved that it is an efficient and attractive technique for cadmium preconcentration and separation at trace level.     

巯基葡聚糖凝胶分离富集微乳液增敏邻硝基苯基荧光酮光度法测定环境样品中痕量镉的研究

报道了在(CPB-OP)微乳液介质中,以pH=10.40硼砂-NaOH为缓冲溶液,镉与邻硝基苯基荧光酮(o-NPF)生成1:3有色配合物,于620 nm处摩尔吸光系数为1.23×10~5L·mol~(-1)·cm~(-1)。镉含量在0～0.76μg·mL~(-1)范围内符合比耳定律,检出限为9.2×10~(-5)μg·mL~(-1)。采用巯基葡聚糖凝胶分离富集,可消除共存离子的干扰。该方法用于水样和污泥样品中的痕量镉的测定,结果满意。