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。     

微乳液1-(2-吡啶偶氮)-2-萘酚分光光度法测定蔬菜样品中的钴

以十二烷基硫酸钠-溴代十六烷基三甲胺(SDS-CIMAB)复合微乳液为介质,对Co(Ⅱ)-1-(2-吡啶偶氮)-2-萘酚的显色反应条件进行了研究.结果表明该体系的λ_(max)=580nm,ε_(580)=3.4×10~4L·mol·cm~(-1),Co(Ⅱ)测定的线性范围为0～2.40mg/L.回收率在96%～103%之间,该法选择性好,用于蔬菜中Co(Ⅱ)含量的测定,得到了满意的结果.     

微乳液--1-(2-吡啶偶氮)-2-萘酚体系测定Co(Ⅱ)

The spectrohpotometric determination of Co(Ⅱ) was studied with 1-( 2 -pyridylazo)-2-naphthol in the sodium dodecyl sulphate/n-heptane/water micr oemulsion medium.The apparent molar absorptivity is 1.84×10⁴ L^.mol -1^.cm^-1 at 575 nm.Beer's law is obeyed in the range of 0～ 50 μg/25 mL for Co(Ⅱ).     

钴(Ⅲ)-1-(2-吡啶偶氮)-2-萘酚络合物的胶束薄层色谱行为研究

本文研究了钴(Ⅲ)-1-(2-吡啶偶氮)-2-萘酚(PAN)络合物的胶束薄层色谱行为,探讨了该络合物的胶束色谱分离机理。以聚酰胺薄片为固定相,6.4％SDS:10％Triton X-100:HAc-NaAc(2.5∶4∶1.5)体系为展开剂,建立了选择性好、灵敏度高的钴的胶束薄层色谱扫描测定法,测定波长为450nm。标准曲线的线性范围为7.5～75纳克/斑点,最小检出量为2.5ng/斑点。方法用于Ni~(2+)、Cu~(2+)等八种金属离子混合液及维生素B~(12)针剂中钴的测定,结果令人满意。     

酪氨酸与1-亚硝基-2-萘酚反应的研究

本文用荧光、分子吸收光谱和电化学等方法研究了在含 Na NO2 的 HNO3溶液中酪氨酸与 1 -亚硝基 - 2 -萘酚的反应 ,该反应最后生成具有荧光性质的酚噻嗪类化合物。于 - 0 .5 3V( vs. SCE)处被还原的反应中间物酚噻嗪类化合物的氧化物可被光还原为酚噻嗪类化合物 ,其分解过程的反应为二级反应 ;反应速度常数为 5× 1 0 - 4L· mol- 1· min- 1。酚噻嗪类化合物的生成过程为一级反应 ,反应速度常数为 0 .0 2 1min     

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。     

微晶酚酞富集-分光光度法测定痕量Zn(II)

建立了一种利用修饰有结晶紫(CV^＋)的微晶酚酞作为固态吸附剂分离富集溶液中痕量Zn(II)的新方法, 富集后的Zn(II)含量可直接用光度法测定. 控制一定条件, Zn(II)能与常见阳离子Ni(II), Cd(II), Al(III), Ca(II), Mg(II), Co(II), Mn(II), Cu(II), Pb(II), Fe(III)等完全分离, 且富集时基本不受, , Br^－, Cl^－, I^－,等阴离子影响. 微晶酚酞对Zn(II)的吸附容量为25.8 mg/g; 富集因数可达200倍, 回收率在97.7%～102%之间, RSD小于2.7%. 该方法已成功应用于实际水样中Zn(II)的富集测定, 结果令人满意.     

1-亚硝基-2-萘酚浊点萃取-火焰原子吸收光谱法对水样中痕量铁的测定

采用以1-亚硝基-2-萘酚为螯合剂、Triton X-114为表面活性剂的新型浊点萃取体系富集水中的痕量铁,并用火焰原子吸收光谱法对铁进行测定。详细探讨了溶液pH值、表面活性剂浓度、络合剂浓度、平衡温度、平衡时间等对浊点萃取及测定灵敏度的影响,优化了实验条件。在最佳条件下测得铁的检出限（S／N=3）为0．42μg·L^-1,富集倍数为32,校准曲线相关系数为0．996。应用该法测定海水、湖水及自来水中的痕量铁,结果满意。     

微晶酚酞富集-分光光度法测定痕量Zn(II)

建立了一种利用修饰有结晶紫(CV^＋)的微晶酚酞作为固态吸附剂分离富集溶液中痕量Zn(II)的新方法, 富集后的Zn(II)含量可直接用光度法测定. 控制一定条件, Zn(II)能与常见阳离子Ni(II), Cd(II), Al(III), Ca(II), Mg(II), Co(II), Mn(II), Cu(II), Pb(II), Fe(III)等完全分离, 且富集时基本不受, , Br^－, Cl^－, I^－,等阴离子影响. 微晶酚酞对Zn(II)的吸附容量为25.8 mg/g; 富集因数可达200倍, 回收率在97.7%～102%之间, RSD小于2.7%. 该方法已成功应用于实际水样中Zn(II)的富集测定, 结果令人满意.     

1-(2-吡啶偶氮)-2-萘酚-过氧化氢光度法测定土壤中痕量钒

对钒(V)与1-(2-吡啶偶氮)-2-萘酚-过氧化氢-十六烷基三甲基溴化铵显色反应进行了试验,结果表明:在1 mol·L-1盐酸介质中,在十六烷基三甲基溴化铵存在下,钒(V)与1-(2-吡啶偶氮)-2-萘酚和过氧化氢反应生成红色多元络合物,络合物的最大吸收波长为577 nm,表观摩尔吸光率为3.04×104L·mol-1·cm-1,钒(V)的质量浓度在1.0 mg·L-1以内符合比耳定律.络合物的组成比为n钒(V):nPAN:n过氧化氢=1:1:1.方法用于土壤试样中痕量钒的测定,测定值的相对标准偏差(n=6)均小于9%,回收率在97.8%～101.5%之间,测得标准样品(GSS-5)中钒的含量为170.45μg·g-1,与标准值(166±9)μg·g-1之间的相对误差为2.7%.     

纳米SiO_2分离富集-火焰原子吸收法测定水中痕量银

研究了纳米SiO_2分离富集-火焰原子吸收法测定水中痕量银的新方法.考察了溶液pH、吸附时间、洗脱条件和干扰离子等因素对Ag~+分离富集的影响,确定了纳米SiO_2对Ag~+吸附的最佳条件.结果表明:在pH 4.1时,纳米SiO_2能定量吸附银,吸附在纳米SiO_2上的Ag~+可用0.5 mol/L HCl+0.5 mol/L硫脲定量洗脱.该法对银的检出限为0.77 ng/mL(3σ,n=11);线性范围为0.005～1.5μg/mL,对0.5μg/mL的Ag~+标液进行7次测定,RSD为3.6%,回收率在94.0%～101.5%之间;方法可用于环境水样中痕量银的测定.     

Cobalt Determination by Means of Flow Injection On-line Sorbent Preconcentration-Flame Atomic Absorption Spectrometry with 1-Nitroso-2-naphthol as a Complexing Reagent

The suitability of 1-nitroso-2-naphthol(NN) as a complexing agent for on-line preconcentration of cobalt eluted on the C_(18) microcolumn by means of the FI-FAAS system was tested. Various parameters affecting the complex formation and its elution were optimized. A 2.3×10~(-3) mol/L reagent solution and the aqueous sample solution acidified with 0.1％ (volume fraction) nitric acid were on-line mixed (6.4 mL/min) on a reaction coil set at (65±1)℃ and flowed through the microcolumn for 30 s. The pH of the mixed solution was adjusted to 3—4 with HNO_3(1 mol/L) or NaOH(1 mol/L). The adsorbed complexes in the microcolumn were eluted into the nebulizer of FAAS in 10 s with ethanol acidified with 1％ HNO_3(3.0 mL/min). A good precision(1.6％ for 100μg/L Co(Ⅱ), n=10), a high enrichment factor 17.2, with detection limit (3σ) 3.2μg/L, and sample throughput (90 h~(-1)) were obtained. The method was applied to the certified reference materials(CRMs), NBS-362 and NBS-364, for the determination of cobalt and the results were in good agreement with the certified values.     

Pre-concentration of trace amounts of manganese in water samples based on (1-(2-pyridylazo)-2-naphthol) modified magnetic nanoparticles

A simple procedure based on magnetic nanoparticles has been developed for analytical purposes. In this method, 1-(2-pyridylazo)-2-naphthol (PAN)-modified magnetic nanoparticles (MNPs) were used for separation and pre-concentration of manganese(II) ions from aqueous samples. This method combines the use of a solution solvent with separation of magnetic nanoparticles from sample solution using a magnet. The influence of different parameters, such as amount of extractant (PAN) loaded on the nanoparticles, pH of solution, adsorption time, amount of modified nanoparticle, type and amount of eluents for desorption of manganese from magnetic nanoparticles were evaluated. The effect of various cationic and anionic interferences on the percentage recovery of manganese was also studied. Manganese ions were adsorped from a solution at pH 9.5 and desorbed from nanoparticles with 10?mL of DMSO?:?HNO₃ (1?:?1, v/v). The detection limit of the proposed method was found to be 0.11?µg?L^?1. The method was employed to recover and determine the level of manganese in different water samples.     

On-line preconcentration and determination of cobalt by chelating microcolumns and flow injection atomic spectrometry

A simple and sensitive flow injection analysis-atomic absorption spectrometric procedure is described for the determination of cobalt. The method is based upon on-line preconcentration of cobalt on a microcolumn of 2-nitroso-1-naphthol immobilized on surfactant coated alumina. The trapped cobalt is then eluted with ethanol (250 μl) and determined by flame atomic absorption spectrometry. The analytical figures of merit for the determination of cobalt are as follows: detection limit (3 S), 0.02 ng ml⁻¹; precision (RSD), 2.8% for 20 ng ml⁻¹ and 1.7% for 70 ng ml⁻¹ of cobalt; enrichment factor, 125 (using 25 ml of sample). The method has been applied to the determination of cobalt in water samples, vitamin B₁₂ and B-complex ampoules and accuracy was assessed through recovery experiment and independent analysis by furnace AAS.     

Ultrasonic-assisted supramolecular solvent-based liquid phase microextraction of mercury as 1-(2-pyridylazo)-2-naphthol complexes from water samples

A separation-preconcentration method based on supramolecular solvent ultrasonic-assisted liquid-phase microextraction (Ss-USA-LPME) for spectrophotometric determination of mercury as 1-(2-pyridylazo)-2-naphthol (PAN) chelates has been established. Red coloured Hg(II)-PAN hydrophobic complex was extracted into the supramolecular phase (1-decanol/THF) at pH 9.5. The extract was separated from aqueous phase by centrifugation, diluted with ethanol and determined by UV–Vis spectrophotometer at λ_max = 560 nm. The influences of important analytical parameters such as pH, amount of PAN, 1-decanol and THF, sample volume and matrix effects for the quantitative recoveries were examined and optimised. Under the optimised experimental conditions, the amount of ligand, 1-decanol and THF were 1.0 × 10^–4 M, 200 µL and 300 µL, respectively. The optimum time of ultrasonic bath and centrifugation were found as 2 min and 5 min. A linear calibration graph was obtained linearly in the concentration ranges of 8.3–1000 µg L^?1. The preconcentration factor was obtained as 20. The limit of detection (LOD) was 2.6 µg L^?1 with the relative standard deviation (RSD) of 2.4% for mercury (C = 100 µg L^?1, n = 7). The validity of the developed Ss-USA-LPME technique was checked with a certified reference material of NIST 1641d. The presented method has been successfully applied to the determination of mercury in water samples.     

Novel separation and preconcentration of trace amounts of copper(II) in water samples based on neocuproine modified magnetic microparticles

A novel, simple method based on magnetically assisted chemical separation (MACS) has been developed for analytical purposes. In this method, neocuproine modified magnetic microparticles was used for selective extraction and preconcentration of copper(II) ions from aqueous solutions. The advantages of this method include consumption of organic solvents almost eliminated and applications on unclear (containing suspended particles) samples without any preliminary filtration step. This method combines simplicity and selectivity of solvent extraction with easy separation of magnetic microparticles from solution with magnet. In addition, it can be considered as a simple method for determination of partition coefficient. The influence of different parameters, such as presence of extractant, amount of extractant loaded on the microparticles, reducing agent, pH, equilibrium time, ionic strength, type and least amount of stripping solution and limit of detection, were evaluated. Also, the effects of various cationic and anionic interferences on the percent recovery of copper were studied. Copper ions were extracted from solution at pH 6 and were stripped from microparticles with 0.5 M HNO₃. Extraction efficiencies for solutions with volumes up to 100 ml were >99%. Limit of detection was 1.5 μg/l. The method was applied to the recovery and determination of copper in different water samples.     

Determination of trace amounts of vanadium by UV-vis spectrophotometric after separation and preconcentration with modified natural clinoptilolite as a new sorbent

Natural clinoptilolite was used as a sorbent material for solid phase extraction and preconcentration of vanadium. The clinoptilolite was first saturated with a cation such as nickel(II) and then modified with benzyldimethyltetradecyleammonium chloride (BDTA) for increasing sorption of 4-(2-pyridylazo)resorcinol (PAR). Vanadium–PAR complex was quantitatively retained on the sorbent by the column method at the pH range 6.2–7.0 at a flow rate of 1 mL min⁻¹. It was removed from the column with 5.0 mL of dimethylformamide solution at a flow rate of 0.8 mL min⁻¹ and determined by UV–vis spectrophotometry at λ_max = 550 nm. 0.031 μg of vanadium can be concentrated from 450 mL of aqueous sample (where detection limit as 0.07 ng mL⁻¹ with preconcentration factor of 90). Relative standard deviation for eight replicate determination of 5.0 μg of vanadium in final solution is 2.1%. The interference of number of anions and cations has been studied in detail to optimize the conditions and method was successfully applied for determination of all vanadium as V(IV) form in standard samples.     

A novel method of the separation/preconcentration and determination of trace molybdenum(VI) in water samples using microcrystalline triphenylmethane loaded with salicyl fluorone

It is the first time that triphenylmethane was used as an adsorbent to preconcentrate and separate trace amount of molybdenum in water samples. The effects of different parameters, such as acidity, stirring time and various metal ions, the amounts of triphenylmethane and salicyl fluorine, etc. on the enrichment yield of molybdenum have been studied to optimize the experimental conditions. Under the optimum conditions, molybdenum can be adsorbed on the surface of microcrystalline triphenylmethane loaded with salicyl fluorone by the intermolecular action strength. The possible reaction mechanism for the enrichment of molybdenum was discussed in detail in this paper. Mo(VI) can be completely separated from Pb(II), Co(II), Cu(II), Cr(III), Ni(II), Hg(II), Zn(II), Cd(II), Fe(III) and Al(III) in the solution. The proposed method was successfully applied to the determination of trace amount of molybdenum in various water samples by spectrophotometry after preconcentration using microcrystalline triphenylmethane. The preconcentration factor is from 83 (500 ml water sample was enriched to 6.0 ml) to 166 (1000 ml water sample was enriched to 6.0 ml). The detection limit is 1.3 × 10⁻⁵ mg l⁻¹ and the linearity is maintained in the concentration range 3.8 × 10⁻³ to 0.36 mg l⁻¹ with a correlation coefficient of 0.9998. The recoveries are in the range of 93.5-104%. The relative standard deviation is 1.8-2.9%. Analytical results obtained with this novel method are very satisfactory.     

A solid phase extraction using a chelate resin immobilizing carboxymethylated pentaethylenehexamine for separation and preconcentration of trace elements in water samples

A chelate resin immobilizing carboxymethylated pentaethylenehexamine (CM-PEHA resin) was prepared, and the potential for the separation and preconcentration of trace elements in water samples was evaluated through the adsorption/elution test for 62 elements. The CM-PEHA resin could quantitatively recover various elements, including Ag, Cd, Co, Cu, Fe, Ni, Pb, Ti, U, and Zn, and rare earth elements over a wide pH range, and also Mn at pH above 5 and V and Mo at pH below 7. This resin could also effectively remove major elements, such as alkali and alkaline earth elements, under acidic and neutral conditions. Solid phase extraction using the CM-PEHA resin was applicable to the determination of 10 trace elements, Cd, Co, Cu, Fe, Mn, Mo, Ni, Pb, V, and Zn, in certified reference materials (EnviroMAT EU-L-1 wastewater and ES-L-1 ground water) and treated wastewater and all elements except for Mn in surface seawater using inductively coupled plasma atomic emission spectrometry. The detection limits, defined as 3 times the standard deviation for the procedural blank using 500 mL of purified water (50-fold preconcentration, n = 8), ranged from 0.003 μg L⁻¹ (Mn) to 0.28 μg L⁻¹ (Zn) as the concentration in 500 mL of solution.     

Use of clinoptilolite loaded with 1-(2-pyridylazo)-2-naphthol as a sorbent for preconcentration of Pb(II), Ni(II), Cd(II) and Cu(II) prior to their determination by flame atomic absorption spectroscopy

A solid phase extraction system for separation and preconcentration of trace amounts of Pb(II), Ni(II), Cd(II) and Cu(II) is proposed. The procedure is based on the adsorption of Pb²⁺, Ni²⁺, Cd²⁺ and Cu²⁺ ions on a column of 1-(2-pyridylazo)-2-naphthol (PAN) immobilised on surfactant-coated clinoptilolite prior to their determinations by Flame Atomic Absorption Spectroscopy (FAAS). The effective parameters including pH, sample volume, sample flow rate and eluent flow rate were also studied. The analytes collected on the column were eluted with 5 mL of 1 mol L^?1 nitric acid. A concentration factor of 180 can be achieved by passing 900 mL of sample through the column. The detection limits (3 s) for Cd, Cu, Pb and Ni were found to be 0.28, 0.12, 0.44 and 0.46 µg L^?1, respectively. The relative SDs at 10 µg L^?1 (n = 10) for analytes were in the range of 1.2–1.4%. The method was applied to the determination of Pb, Ni, Cd and Cu in water samples.