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4.7: Chapter Summary and Key Terms

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    379474
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    Chapter Summary

    In this chapter we introduced three electrochemical methods of analysis: potentiometry, coulometry, and voltammetry. In potentiometry we measure the potential at an indicator electrode without allowing any significant current to pass through the electrochemical cell, and use the Nernst equation to calculate the analyte’s activity after accounting for junction potentials.

    There are two broad classes of potentiometric electrodes: metallic electrodes and membrane electrodes. The potential of a metallic electrode is the result of a redox reaction at the electrode’s surface. An electrode of the first kind responds to the concentration of its cation in solution; thus, the potential of a Ag wire is determined by the activity of Ag+ in solution. If another species is in equilibrium with the metal ion, the electrode’s potential also responds to the concentration of that species. For example, the potential of a Ag wire in a solution of Cl responds to the concentration of Cl because the relative concentrations of Ag+ and Cl are fixed by the solubility product for AgCl. We call this an electrode of the second kind.

    The potential of a membrane electrode is determined by a difference in the composition of the solution on each side of the membrane. Electrodes that use a glass membrane respond to ions that bind to negatively charged sites on the membrane’s surface. A pH electrode is one example of a glass membrane electrode. Other kinds of membrane electrodes include those that use insoluble crystalline solids or liquid ion-exchangers incorporated into a hydrophobic membrane. The F ion-selective electrode, which uses a single crystal of LaF3 as the ion-selective membrane, is an example of a solid-state electrode. The Ca2+ ion-selective electrode, in which the chelating ligand di-(n-decyl)phosphate is immobilized in a PVC membrane, is an example of a liquid-based ion-selective electrode.

    Potentiometric electrodes are designed to respond to molecules by using a chemical reaction that produces an ion whose concentration is determined using a traditional ion-selective electrode. A gas-sensing electrode, for example, includes a gas permeable membrane that isolates the ion-selective electrode from the gas. When a gas-phase analyte diffuses across the membrane it alters the composition of the inner solution, which is monitored with an ion-selective electrode. An enzyme electrodes operate in the same way.

    Coulometric methods are based on Faraday’s law that the total charge or current passed during an electrolysis is proportional to the amount of reactants and products participating in the redox reaction. If the electrolysis is 100% efficient—which means that only the analyte is oxidized or reduced—then we can use the total charge or total current to determine the amount of analyte in a sample. In controlled-potential coulometry we apply a constant potential and measure the resulting current as a function of time. In controlled-current coulometry the current is held constant and we measure the time required to completely oxidize or reduce the analyte.

    In voltammetry we measure the current in an electrochemical cell as a function of the applied potential. There are several different voltammetric methods that differ in terms of the choice of working electrode, how we apply the potential, and whether we include convection (stirring) as a means for transporting of material to the working electrode.

    Polarography is a voltammetric technique that uses a mercury electrode and an unstirred solution. Normal polarography uses a dropping mercury electrode, or a static mercury drop electrode, and a linear potential scan. Other forms of polarography include normal pulse polarography, differential pulse polarography, staircase polarography, and square-wave polarography, all of which use a series of potential pulses.

    In hydrodynamic voltammetry the solution is stirred using either a magnetic stir bar or by rotating the electrode. Because the solution is stirred a dropping mercury electrode is not used; instead we use a solid electrode. Both linear potential scans and potential pulses can be applied.

    In stripping voltammetry the analyte is deposited on the electrode, usually as the result of an oxidation or reduction reaction. The potential is then scanned, either linearly or using potential pulses, in a direction that removes the analyte by a reduction or oxidation reaction.

    Amperometry is a voltammetric method in which we apply a constant potential to the electrode and measure the resulting current. Amperometry is most often used in the construction of chemical sensors for the quantitative analysis of single analytes. One important example is the Clark O2 electrode, which responds to the concentration of dissolved O2 in solutions such as blood and water.

    Key Terms

    amalgam

    anodic current

    cathode

    controlled-current coulometry

    coulometric titrations

    current efficiency

    diffusion layer

    electrochemically irreversible

    electrode of the second kind

    enzyme electrodes

    galvanostat

    hanging mercury drop electrode

    ionophore

    limiting current

    mediator

    migration

    overpotential

    potentiometer

    redox electrode

    salt bridge

    silver/silver chloride electrode

    static mercury drop electrode

    voltammetry

    amperometry

    asymmetry potential

    cathodic current

    controlled-potential coulometry

    coulometry

    cyclic voltammetry

    dropping mercury electrode

    electrochemically reversible

    electrochemistry

    faradaic current

    gas-sensing electrode

    hydrodynamic voltammetry

    ion selective electrode

    liquid-based ion-selective electrode

    membrane potential

    nonfaradaic current

    peak current

    potentiostat

    reference electrode

    saturated calomel electrode

    solid-state ion-selective electrodes

    stripping voltammetry

    voltammogram

    anode
    auxiliary electrode

    charging current

    convection

    counter electrode

    diffusion

    electrical double layer

    electrode of the first kind

    electrogravimetry

    Faraday’s law

    glass electrode

    indicator electrode

    junction potential

    mass transport

    mercury film electrode

    Ohm’s law

    polarography

    pulse polarography

    residual current

    selectivity coefficient

    standard hydrogen electrode

    total ionic strength adjustment buffer

    working electrode


    4.7: Chapter Summary and Key Terms is shared under a not declared license and was authored, remixed, and/or curated by LibreTexts.

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