An efficient approach to designing and optimizing the analysis of Ni(II) by AdCSV in seawater

A highly sensitive voltammetric method was developed for the determination of nickel in seawater at nanomolar concentrations. The measurement is based on the differential pulse cathodic adsorptive stripping of Ni(II) complexed with pyridoxal salicyloylhydrazone at a hanging mercury drop electrode. O...

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Bibliographic Details
Published in:Talanta (Oxford) 2010-10, Vol.82 (5), p.1749-1756
Main Authors: Aouarram, A., Galindo-Riaño, M.D., García-Vargas, M., Stitou, M., El Yousfi, F., Espada-Bellido, E.
Format: Article
Language:English
Subjects:
Adsorption
Adsorptive stripping voltammetry
Analytical chemistry
Brackish
Chemistry
Deposition
Electric potential
Electrochemical methods
Electrochemical Techniques - instrumentation
Electrochemical Techniques - methods
Electrodes
Exact sciences and technology
Experimental design
Indicators and Reagents
Ligands
Limit of Detection
Marine
Mercury - chemistry
Morocco
Nanostructure
Nickel
Nickel - analysis
Optimization
Pyridoxal salicyloylhydrazone
Reference Standards
Research Design
Sea water
Seawater
Seawater - analysis
Seawater - chemistry
Spectrophotometry, Ultraviolet
Trace Elements - analysis
Voltage
Water Pollutants, Chemical - analysis
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Summary:A highly sensitive voltammetric method was developed for the determination of nickel in seawater at nanomolar concentrations. The measurement is based on the differential pulse cathodic adsorptive stripping of Ni(II) complexed with pyridoxal salicyloylhydrazone at a hanging mercury drop electrode. Optimal conditions were found following a two-step study strategy based on a Plackett Burman design and subsequently a modified simplex method. They were: deposition potential −0.8 V; deposition time 120 s; differential pulse scan mode; pulse amplitude −0.07 V; pulse time 0.04 s; voltage step 0.017 V; time interval for voltage step 0.05 s; supporting electrolyte ammonium chloride/ammonia (0.08 M, pH = 8.9) and concentration of PSH 5.32 × 10 −6 M. The response of the system was found to be linear in a range of Ni concentrations from 0 to 306.7 × 10 −9 M. The detection limit was found to be 0.04 × 10 −9 M of Ni(II). The precision of the method was 1.4% for 3.4 × 10 −8 M of Ni(II) and 1.48% for the blank at a significance level of 95% ( n = 9). The method was free from interferences of inorganic salts and trace metals at usual concentrations in seawater. The application to seawater was demonstrated by analysis of CRM 505 and LGC 6016 certified reference estuarine water and real seawater samples from Tangier Bay (Morocco).
ISSN:0039-9140
1873-3573
DOI:10.1016/j.talanta.2010.07.069