2015
DOI: 10.1021/acs.analchem.5b02355
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Voltammetric Characterization of Ion–Ionophore Complexation Using Thin Polymeric Membranes: Asymmetric Thin-Layer Responses

Abstract: Selective ion-ionophore complexation in a polymeric membrane is crucial to various sensing applications. In this work, we report on a novel voltammetric approach based on a thin polymeric membrane to determine the stoichiometry and overall formation constant of an ion-ionophore complex. With this approach, a ∼1.6 μm thick ionophore-doped membrane contacts an aqueous solution containing an excess amount of a target ion to facilitate voltammetric ion transfer across the membrane/water interface. Advantageously, … Show more

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Cited by 19 publications
(84 citation statements)
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“…11 Specifically, the forward (or reverse) peak of a kinetically controlled CV with n I = 1 is broader at the positive (or negative) side of the peak potential. This asymmetry contrasts to the asymmetric forward (or reverse) peak of a reversible voltammogram with n I = 2 or greater, which is broader at the negative (or positive) side of the peak potential.…”
Section: Theorymentioning
confidence: 99%
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“…11 Specifically, the forward (or reverse) peak of a kinetically controlled CV with n I = 1 is broader at the positive (or negative) side of the peak potential. This asymmetry contrasts to the asymmetric forward (or reverse) peak of a reversible voltammogram with n I = 2 or greater, which is broader at the negative (or positive) side of the peak potential.…”
Section: Theorymentioning
confidence: 99%
“…We assume that an excess amount of an analyte or interfering ion is present in its separate aqueous solution so that the ion-transfer reaction can be treated as a first-order reaction, i.e., nXnormalLfalse(normalmfalse)kb,Xkf,XLnnormalXXznormalXfalse(normalmfalse)where an ion, XznormalXfalse(=IznormalIor Jznormaljfalse), forms 1: n X (= n I or n J , respectively) complexes with an ionophore, L. This model considers the kinetics of facilitated ion transfer within a wide range from reversible cases to irreversible cases, whereas only reversible cases were considered in previous models. 11,12 The rate constants for forward and reverse reactions, k f,X and k b,X , respectively, are given by the Butler-Volmer type model 8 to yield kf,X=knormalX0LnormalTnnormalX1exp[αnormalXznormalXF(normalΔnormalwnormalmϕnormalΔnormalwnormalmϕnormalLX0)RT] kb,X=kX0exp[(1αnormalX)znormalXF(normalΔnormalwnormalmϕnormalΔnormalwnormalmϕnormalLX0)RT]where kX0 is the standard ion-transfer rate constant, α X is transfer coefficient (≈ 0.5 as determined experimentally 8 ), L T is the total concentration of the ionophore, Δwmϕ is the phase boundary potential across the membrane/water interface, and...…”
Section: Theorymentioning
confidence: 99%
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