Lability of nanoparticulate metal complexes in electrochemical speciation analysis

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 equilibr...

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Published in	Journal of solid state electrochemistry Vol. 20; no. 12; pp. 3255 - 3262
Main Authors	van Leeuwen, Herman P., Town, Raewyn M.
Format	Journal Article
Language	English
Published	Berlin/Heidelberg Springer Berlin Heidelberg 01.12.2016 Springer Nature B.V
Subjects	Analytical Chemistry Binding sites Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Chemodynamics Condensed Matter Physics Coordination compounds Diffusion layers Electrochemistry Electrodes Energy Storage Intraparticulate reaction layer Ion exchange Lability Metal complexes Metal ions Nanoparticles Original Paper Physical Chemistry Speciation Intraparticulate reaction layer Ion exchange Lability Metal complexes Chemodynamics
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ISSN	1432-8488 1433-0768
DOI	10.1007/s10008-016-3372-7

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Abstract	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.
AbstractList	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 M2+ 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 = (DM/ka ′)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. 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.
Author	van Leeuwen, Herman P. Town, Raewyn M.
Author_xml	– sequence: 1 givenname: Herman P. surname: van Leeuwen fullname: van Leeuwen, Herman P. email: herman.vanleeuwen@wur.nl organization: Physical Chemistry and Soft Matter, Wageningen University & Research – sequence: 2 givenname: Raewyn M. surname: Town fullname: Town, Raewyn M. organization: Department of Physics, Chemistry and Pharmacy, University of Southern Denmark
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Snippet	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...
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SubjectTerms	Analytical Chemistry Binding sites Characterization and Evaluation of Materials Chemistry Chemistry and Materials Science Chemodynamics Condensed Matter Physics Coordination compounds Diffusion layers Electrochemistry Electrodes Energy Storage Intraparticulate reaction layer Ion exchange Lability Metal complexes Metal ions Nanoparticles Original Paper Physical Chemistry Speciation
Title	Lability of nanoparticulate metal complexes in electrochemical speciation analysis
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