Metal speciation dynamics in colloidal ligand dispersions. Part 3: Lability features of steady-state systems

Pinheiro, José Paulo; Domingos, Rute F.; Minor, Marcel; Leeuwen, Herman P. van

doi:10.1016/j.jelechem.2006.07.004

Cited by 17 publications

(15 citation statements)

References 17 publications

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“…These results are basically similar to the correction coefficient for the overall association and dissociation rate constants k a and k d as proposed by Pinheiro et al [23] and experimentally verified using metal complexes with silica NPs and surface-functionalized latex NPs [35,36]. As is clear now from the present analysis, the derived "lability" is actually an expression of the local chemodynamics of the particle in the surrounding medium.…”

Section: The Hard Np Case Of Surface Complexationsupporting

confidence: 91%

Lability of nanoparticulate metal complexes in electrochemical speciation analysis

Leeuwen

Town

2016

J Solid State Electrochem

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Lability concepts are elaborated for metal complexes with soft (3D) and hard (2D) aqueous nanoparticles. In the presence of a non-equilibrium sensor, e.g. a voltammetric electrode, the notion of lability for nanoparticulate metal complexes, M-NP, reflects the ability of the M-NP to maintain equilibrium with the reduced concentration of the electroactive free M 2+ in its diffusion layer. Since the metal ion binding sites are confined to the NP body, the conventional reaction layer in the form of a layer adjacent to the electrode surface is immaterial. Instead an intraparticulate reaction zone may develop at the particle/ medium interface. Thus the chemodynamic features of M-NP complexes should be fundamentally different from those of molecular systems in which the reaction layer is a property of the homogeneous solution (μ = (D M /k a ′ ) 1/2 ). For molecular complexes, the characteristic timescale of the electrochemical technique is crucial in the lability towards the electrode surface. In contrast, for nanoparticulate complexes it is the dynamics of the exchange of the electroactive metal ion with the surrounding medium that governs the effective lability towards the electrode surface.

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Section: The Hard Np Case Of Surface Complexationsupporting

confidence: 91%

Lability of nanoparticulate metal complexes in electrochemical speciation analysis

Leeuwen

Town

2016

J Solid State Electrochem

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“…The system is said to be dynamic or static when the rates of these volume reactions are fast or slow, respectively, on the effective time scale t of the experiments, that is, k a * ρ L V t , k d * t ≫ 1 or k a * ρ L V t , k d * t ≪ 1. ,,, For the former situation, we further distinguish nonlabile and labile complexes, that is, cases where the flux J T of metal species is predominantly controlled by the dissociation kinetic flux and by the diffusive flux of complexes, respectively. , The ratio between kinetic and diffusive flux (denoted as J kin * and J dif * , respectively) is expressed by the lability criterion defined by scriptL * = J kin * / J dif * . Equivalently, scriptL * may be written in the concise form scriptL * = ( δ̅ / μ r − 1 ) / ( 1 + ε K * ′ ) where ε = D p / D M stands for the ratio between the diffusion coefficient of the particle and that of M, μ r = [ D M /( k a * ρ L V )] 1/2 is the so-called reaction layer thickness defined by the mean lifetime of free metal ion M and derived from the rate constant k a * = K * k d * for the (re)association reaction with the colloidal ligand particle. − Under the condition adopted here for the SSCP electrochemical measurements, the steady-state diffusion layer thickness is fixed by gentle hydrodynamic conditions so that δ̅ = 1.61 D̅ 1/3 ω –1/2 υ 1/6 , , where D̅ is the effective diffusion coefficient defined by D̅ = D M (1 + εK *′)(1 + K *′) −1 , ω is the rotation speed of the working electrode, and υ is the kinematic viscosity of water. The limiting dynamic situations of labile and nonlabile particulate metal complexes correspond to scriptL * ≫ 1 and scriptL * ≪ 1, respectively .…”

Section: Theorymentioning

confidence: 99%

“…Equivalently, scriptL * may be written in the concise form scriptL * = ( δ̅ / μ r − 1 ) / ( 1 + ε K * ′ ) where ε = D p / D M stands for the ratio between the diffusion coefficient of the particle and that of M, μ r = [ D M /( k a * ρ L V )] 1/2 is the so-called reaction layer thickness defined by the mean lifetime of free metal ion M and derived from the rate constant k a * = K * k d * for the (re)association reaction with the colloidal ligand particle. − Under the condition adopted here for the SSCP electrochemical measurements, the steady-state diffusion layer thickness is fixed by gentle hydrodynamic conditions so that δ̅ = 1.61 D̅ 1/3 ω –1/2 υ 1/6 , , where D̅ is the effective diffusion coefficient defined by D̅ = D M (1 + εK *′)(1 + K *′) −1 , ω is the rotation speed of the working electrode, and υ is the kinematic viscosity of water. The limiting dynamic situations of labile and nonlabile particulate metal complexes correspond to scriptL * ≫ 1 and scriptL * ≪ 1, respectively . In the Supporting Information, we briefly recall the strategy to experimentally derive scriptL * from SSCP data …”

Section: Theorymentioning

confidence: 99%

Impact of Electrostatics on the Chemodynamics of Highly Charged Metal–Polymer Nanoparticle Complexes

2013

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In this work, the impact of electrostatics on the stability constant, the rate of association/dissociation, and the lability of complexes formed between Cd(II), Pb(II), and carboxyl-modified polymer nanoparticles (also known as latex particles) of radius ∼ 50 nm is systematically investigated via electroanalytical measurements over a wide range of pHs and NaNO3 electrolyte concentrations. The corresponding interfacial structure and key electrostatic properties of the particles are independently derived from their electrokinetic response, successfully interpreted using soft particle electrohydrodynamic formalism, and complemented by Förster resonance energy transfer (FRET) analysis. The results underpin the presence of an ∼0.7-1 nm thick permeable and highly charged shell layer at the surface of the polymer nanoparticles. Their electrophoretic mobility further exhibits a minimum versus NaNO3 concentration due to strong polarization of the electric double layer. Integrating these structural and electrostatic particle features with recent theory on chemodynamics of particulate metal complexes yields a remarkable recovery of the measured increase in complex stability with increasing pH and/or decreasing solution salinity. In the case of the strongly binding Pb(II), the discrepancy at pH > 5.5 is unambiguously assigned to the formation of multidendate complexes with carboxylate groups located in the particle shell. With increasing pH and/or decreasing electrolyte concentration, the theory further predicts a kinetically controlled formation of metal complexes and a dramatic loss of their lability (especially for lead) on the time-scale of diffusion toward a macroscopic reactive electrode surface. These theoretical findings are again shown to be in agreement with experimental evidence.

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“…We are especially interested in the application in trace metal binding in colloidal dispersions [21][22][23].…”

Section: Sscp For Metal Ion Speciation Studies: Simple Labile System mentioning

confidence: 99%

Evaluation of nanometer thick mercury film electrodes for stripping chronopotentiometry

Rocha

Pinheiro

Carapuça

2007

Journal of Electroanalytical Chemistry

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In this work, the performance and applicability of the thin mercury film electrode (TMFE) in the heavy metal speciation, by stripping chronopotentiometry (SCP), were exploited. The TMFE thickness was optimized and a 7.6 nm mercury film was selected. This TMFE was mechanically stable and able to perform 60 SCP consecutive measurements, with no significant variation in the analytical signal of lead(II) (RSD less than 2%). Due to the small electrode thickness the measurements were performed under conditions of complete depletion over a wide oxidation current (I s ) range, i.e., within the interval [75-500] · 10 À9 A. The limit of detection (3r) for lead(II) was 2.4 · 10 À9 M for a deposition time of 40 s and an oxidation current of 75 · 10 À9 A. The TMFE was successfully applied to the construction of SSCP experimental waves, which were in conformity to those predicted by the theory. The stability constant calculated (K 0 ) for the Pb(II)-carboxylated latex nanospheres system using a TMFE, agreed with the one obtained using the HMDE, for identical experimental conditions.

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Metal speciation dynamics in colloidal ligand dispersions. Part 3: Lability features of steady-state systems

Cited by 17 publications

References 17 publications

Lability of nanoparticulate metal complexes in electrochemical speciation analysis

Lability of nanoparticulate metal complexes in electrochemical speciation analysis

Impact of Electrostatics on the Chemodynamics of Highly Charged Metal–Polymer Nanoparticle Complexes

Evaluation of nanometer thick mercury film electrodes for stripping chronopotentiometry

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