1. Sequential injection chromatography with post-column reaction/derivatization for the determination of transition metal cations in natural water samples
- Author
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Petr Chocholouš, Burkhard Horstkotte, Petr Solich, Hana Sklenářová, and Patrícia Jarošová
- Subjects
Analyte ,Formates ,Formic acid ,Pyridines ,Iron ,Analytical chemistry ,chemistry.chemical_element ,Fresh Water ,Resorcinol ,Zinc ,Analytical Chemistry ,chemistry.chemical_compound ,Sodium sulfate ,Derivatization ,Picolinic Acids ,Chromatography ,Sodium formate ,Sulfates ,Drinking Water ,Resorcinols ,chemistry ,Reagent ,Mineral Waters ,Copper ,Water Pollutants, Chemical - Abstract
In this work, the applicability of Sequential Injection Chromatography for the determination of transition metals in water is evaluated for the separation of copper(II), zinc(II), and iron(II) cations. Separations were performed using a Dionex IonPAC™ guard column (50mm×2mm i.d., 9 µm). Mobile phase composition and post-column reaction were optimized by modified SIMPLEX method with subsequent study of the concentration of each component. The mobile phase consisted of 2,6-pyridinedicarboxylic acid as analyte-selective compound, sodium sulfate, and formic acid/sodium formate buffer. Post-column addition of 4-(2-pyridylazo)resorcinol was carried out for spectrophotometric detection of the analytes׳ complexes at 530nm. Approaches to achieve higher robustness, baseline stability, and detection sensitivity by on-column stacking of the analytes and initial gradient implementation as well as air-cushion pressure damping for post-column reagent addition were studied. The method allowed the rapid separation of copper(II), zinc(II), and iron(II) within 6.5min including pump refilling and aspiration of sample and 1mmol HNO3 for analyte stacking on the separation column. High sensitivity was achieved applying an injection volume of up to 90µL. A signal repeatability of2% RSD of peak height was found. Analyte recovery evaluated by spiking of different natural water samples was well suited for routine analysis with sub-micromolar limits of detection.
- Published
- 2014