AGNES: a new electroanalytical technique for measuring free metal ion concentration

Galceran, Josep; Companys, Encarnació; Puy, Jaume; Cecília, Joan; Garces, Josep Lluis

doi:10.1016/j.jelechem.2003.11.017

Cited by 107 publications

(178 citation statements)

References 36 publications

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“…A differential pulse polarography experiment with the largest mercury drop (radius 2.03×10 −4 m, so that the planar electrode expression (Galceran et al 2004) applies), and with a modulation amplitude of 0.04995 V, was performed along with the calibration in order to obtain the E 1 value (corresponding to a desired Y) for the AGNES experiment. The potential program for Cd consists in applying two potential steps in the first stage: (1) E 1,a under reduction diffusion-limited conditions, corresponding to Y 1,a =1×10 8 for t 1,a =100-600 s (with stirring); (2) E 1,b corresponding to Y=100 for t 1,b =300-1,800 s. The waiting time (without stirring) was t w =50 s; (3) E 2 corresponding to Y 1,a =1× 10 −8 under re-oxidation diffusion-limited conditions for 50 s, with the response current being read at t 2 =0.20 s. The program Visual MINTEQ (version 2.5.3) (Allison et al 1999) was used to determine the free metal concentration along the calibration in order to calculate the h-value (a proportionality factor).…”

Section: Agnes Parametersmentioning

confidence: 99%

Stability of core/shell quantum dots—role of pH and small organic ligands

Domingos¹,

Franco²,

Pinheiro

2013

Environ Sci Pollut Res

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The improvement of knowledge about the toxicity and even processability, and stability of quantum dots (QD) requires the understanding of the relationship between the QD binding head group, surface structure, and interligand interaction. The scanned stripping chronopotentiometry and absence of gradients and Nernstian equilibrium stripping techniques were used to determine the concentration of Cd dissolved from a polyacrylate-stabilized CdTe/ CdS QD. The effects of various concentrations of small organic ligands such as citric acid, glycine, and histidine and the roles of pH (4.5-8.5) and exposure time (0-48 h) were evaluated. The highest QD dissolution was obtained at the more acidic pH in absence of the ligands (52 %) a result of the CdS shell solubility. At pH 8.5 the largest PAA ability to complex the dissolved Cd leads to a further QD solubility until the equilibrium is reached (24 % of dissolved Cd vs. 4 % at pH 6.0). The citric acid presence resulted in greater QD dissolution, whereas glycine, an amino acid, acts against QD dissolution. Surprisingly, the presence of histidine, an amino acid with an imidazole functional group, leads to the formation of much strong Cd complexes over time, which may be non-labile, inducing variations in the local environment of the QD surface.

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Section: Agnes Parametersmentioning

confidence: 99%

Stability of core/shell quantum dots—role of pH and small organic ligands

Domingos¹,

Franco²,

Pinheiro

2013

Environ Sci Pollut Res

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“…Absence of gradients and nernstian equilibrium stripping (AGNES) is a recently electroanalytical technique [1] specifically designed for the determination of free metal ion concentration of amalgamating elements. One essential feature is the need to reach a special situation (called ''target'' for convenience) by the end of the deposition (or first stage), so that key parameters of this technique, such as deposition time and deposition potential have to be selected judiciously, especially if one desires to achieve the target within the minimum deposition time (or to reach the lowest limit of detection for a given deposition time).…”

Section: Introductionmentioning

confidence: 99%

The use of microelectrodes with AGNES

Huidobro¹,

Companys²,

Puy³

et al. 2007

Journal of Electroanalytical Chemistry

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Absence of gradients and nernstian equilibrium stripping (AGNES) is a new electroanalytical technique designed to determine free heavy metal ion concentrations in solutions. AGNES had been applied, up to date, with conventional equipment such as the hanging mercury drop electrode (HMDE). Due to their much smaller volume, microelectrodes can reach a given preconcentration factor within a much shorter deposition time, so their use for AGNES has been evaluated in this work. For the particular case of the mercury microelectrode deposited onto an Ir disk (radius around 5 lm), AGNES has been successfully used for speciation purposes in the system Pb + PDCA (pyridinedicarboxylic acid). However, due to a relatively large capacitive current, which decays slowly, the limit of quantification for such microelectrodes has only been reduced by one half with respect to that of the HMDE.

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“…20 The potential program for the AGNES experiment consisted in applying three potential steps: 23 (i) E 1,a under reduction diffusion limited conditions, corresponding to Y 1,a = 1 Â 10 8 for a time t 1,a (with stirring). The suitable t 1,a depends on the desired gain Y (or Y 1,b ) applied: from previous experiments, it is known that t 1,a = 35 s for Y 1,b = 50;…”

Section: Agnes Parametersmentioning

confidence: 99%

“…19 An additional and independent measurement of the free metal concentrations can be obtained from the voltammetric stripping technique AGNES. 20 It is the aim of this paper to provide experimental evidence of this enhancement by measuring the metal flux in different systems with a mercury electrode by using SSCP. Two systems have been analyzed: Cd/NTA/glycine and Cd/NTA/citric acid, as two examples of a fixed inert complex (CdNTA) with two different labile complexes.…”

Section: Introductionmentioning

confidence: 99%

Experimental verification of the metal flux enhancement in a mixture of two metal complexes: the Cd/NTA/glycine and Cd/NTA/citric acid systems

Pinheiro

Salvador

Companys

et al. 2010

Phys. Chem. Chem. Phys.

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Rigorous computation of the metal flux crossing a limiting surface of a system that contains a mixture of 1 : 1 metal complexes under steady-state planar diffusion in a finite domain and under excess of ligand conditions predicts, for some cases, an enhancement of the metal flux with respect to that expected in a system with independent complexes. Indeed, the coupling of the dissociation kinetics of both complexes can yield higher metal fluxes than expected with important environmental implications. By using the voltammetric techniques AGNES and stripping chronopotentiometry, this paper provides experimental evidence of this enhancement for two systems: Cd/NTA/glycine and Cd/NTA/citric acid. The flux measured in both cases is in good agreement with the flux computed for the global system, exhibiting maximum enhancement ratios above 20%. Theoretical discussion of the flux enhancement factors and of the conditions for this enhancement are also provided.

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AGNES: a new electroanalytical technique for measuring free metal ion concentration

Cited by 107 publications

References 36 publications

Stability of core/shell quantum dots—role of pH and small organic ligands

Stability of core/shell quantum dots—role of pH and small organic ligands

The use of microelectrodes with AGNES

Experimental verification of the metal flux enhancement in a mixture of two metal complexes: the Cd/NTA/glycine and Cd/NTA/citric acid systems

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