Elaheh Khazaeli scite author profile

The reliable and rapid dispersive liquid-liquid microextraction (DLLME) was applied to highly selective preconcentration and extraction of ultra-trace Zn 2+ levels as a prior step to its determination by graphite furnace atomic absorption spectrometry (GFAAS). In this method, N,N-phenylenebis (salicylideaminato) (L) was used as a Zn 2+ selective complexing agent. A mixture containing a dispersing solvent (methanol), extraction solvent (chloroform), and proper levels of the chelating agent was rapidly injected into the 5 mL aqueous sample containing 2.5% (w/v) sodium chloride and Zn 2+ , which resulted in a cloudy solution. After 5 min of centrifuging at 5500 rpm, the fine droplets of extraction solvent were sedimented at the bottom of the conical test tube. The variables of interest in the DLLME method, such as extraction and dispersion solvent types and volumes, sample solution pH, extraction time, chelating agent concentration, and ionic strength, were investigated and optimized using a chemometrics approach. Then, after the preliminary experiment, the factors presenting significant positive effects on the analytical response (pH, salt effect, extraction solvent, and ligand concentration) were considered in a further response surface methodology based on central composite design to optimize the operational conditions for DLLME. It was found that extraction time and common interfering ions had no significant effect on the extraction recovery. Under the selected conditions, the linear range was 0.2-100 ng mL À1 and limit of detection was 0.05 ng mL À1 for most of the analytes. The relative standard deviation (R.S.D) for 2 ng mL À1 Zn 2+ was 4.87% (n ¼ 15) and the enrichment factor was 167 from 5 mL of the aqueous sample. In the optimum conditions, the present method was successfully applied to the preconcentration and Zn 2+ determination in different natural oil and water samples. Fig. 1 (A) Chemical structure of the ligand. (B) Absorbance spectra of a 1 Â 10 À6 mol L À1 solution of L in methanol at different Zn 2+ concentrations. (C) Influence of pH on the Zn 2+ recovery; extraction conditions: sample volume, 5 mL; dispersing solvent volume, 450 mL methanol; extraction solvent, 35 mL CHCl 3 ; chelating agent 1 Â 10 À6 mol L À1 ; pH ¼ 6; salt concentration: 2.5% (w/v) and 2.00 ng mL À1 Zn 2+ concentration. Anal. MethodsThis journal is

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Ni(II) analysis in food and environmental samples by liquid-liquid microextraction combined with electro-thermal atomic absorption spectrometry

Khazaeli

Haddadi

Zargar

et al. 2017

Microchemical Journal

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An agarose based optical membrane sensor for selective monitoring of trace nickel ions

Alizadeh

Rezaei

Khazaeli

2021

Journal of Photochemistry and Photobiology A: Chemistry

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Elaheh Khazaeli

A new triazene-1-oxide derivative, immobilized on the triacetyl cellulose membrane as an optical Ni2+ sensor

Response surface methodology based on central composite design as a chemometric tool for optimizing dispersive liquid–liquid microextraction for determining ultra-trace amounts of zinc in oil and water samples

Ni(II) analysis in food and environmental samples by liquid-liquid microextraction combined with electro-thermal atomic absorption spectrometry

An agarose based optical membrane sensor for selective monitoring of trace nickel ions

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