Citation: Cai Shengmin, Liu Changyi, S. M. Wilhelm, Norman Hackerman. INSTRUMENTION FOR RAPID MEASUREMENT OF THE CAPACITANCE AND RESISTANCE OF ELECTROLYTIC CELL[J]. Acta Physico-Chimica Sinica, ;1986, 2(01): 22-29. doi: 10.3866/PKU.WHXB19860104 shu

INSTRUMENTION FOR RAPID MEASUREMENT OF THE CAPACITANCE AND RESISTANCE OF ELECTROLYTIC CELL

  • Received Date: 20 December 1984
    Available Online: 15 February 1986

  • A.C. impedance is an extremely valuable tool for the interpretation of electrochemical reaction mechanisms and

    cell characteristics.
    We describe here instrumentation capable of measuring the capacitance and resistance of electrochemical cells under

    conditions of varying cell voltage and/or measuring frequency.
    Circuit
    The principle on which the circuit is based (Figure 1) is that of phase-sensitive detection and is similar to methods

    described previously [1] with two exceptions. In most impedance measurement circuits, the cell voltage is modulated and the

    corresponding response of the cell current monitored. This sometimes presents aproblem in separating the cell response from

    that of the control circuit and generally requires larger perturbation signals. In this case, a small (<10 μA) current

    signal is applied with the control circuit isolated through L. Second, in this system, the measuuring frequency can be varied

    using a ramp generator coupled to a voltage-controlled frequency oscillator.
    The lock-in amplifier that was used (PAR Model 5204) contains two phasesensitive detectors that are driven by ortho nal

    reference signals. Both cell resistance (in phase) and cell reactance (-1/ωC, quadrature) can be monitored simultaneously.

    Any phase shift caused by the measurement circuit can be offset by substituting a standard resistor for the electrochemical

    cell and adjusting the phase control of the lock-in amplifier. In all cases tested, this adjustment was less than ±2°.
    Applications
    The response of the measuring system to a dummy cell consisting of a 50 Ω resistor in series with a 50 Ω resistor and 1 μF

    capacitor in parallel gave a spectrum that agreed with the theoretical prediction within 2%. In Figure 2, the differential

    capacitance of a dropping mercury electrode in 1 molL~(-1) Na_2SO_4 solution obtained using the system under discussion is

    compared with Grahame′s original data [2,3]. Curve b is for a solution saturated with N-heptyl alcohol. The agreement is

    quite od with the exception of the adsorption peaks. The peak heights should be sensitive to the perturbation signal

    magnitude in that higher amplitude perturbations tend to “average out” sharp peaks. The small current signal that was used

    in the present case seems to improve the resolution of the capacitance peaks.
    There an error in the original report by Grahame(2). The abscissas in Figures 20 and 21 should read, “E relative to the

    normal mercury/mercurous sulfate electrode” instead of “E relative to the normal calomel electrode”. The reasons are as

    follows:
    1) Our numerous experiments using SCE reference electrode and normal mercury/mercurous sulfate reference electrode show

    Grahame′s abscissa (in fig.21) is incorrect.
    2) The related fig.20 of Grahame′s paper was quoted from uy (Ann. Chim. Phys. 8, 291). However, we found out in this

    original paper uy used a large mercury pool asreference electrode. Since it is a normal sulfate solution, the

    electrodepotential should related to mercury/mercurous sulfate electrode but not to NCE electrode.
    3) From table 1 on page 451 in Grahame′s paper, the E~(MAX) (potential of the electrocapillary maximum) in Na_2SO_4 solution

    is -0.48 V versus NCE. It agrees well with Frumkin′s data -0.47 V versus NCE (A.H.фрумкин et.al. КИНЕТИКА Э

    ЛЕКТРОДНЫХ ПРОЦЕССОВ. 1952, p.31, table 1). If in fig.20 the maximum is -0.85 V “relative to normal

    mercury/mercurous sulfate electrode”, since N-mercury/mercurous electrode is 0.335 V more positive that NCE, now the maximum

    appears at -0.515 V releative to NCE electrode. It agrees well with other data.
    Our intention of pointing out this minor error in Grahame′s paper is merely because this paper is generally accepted as the

    classical paper with most authority in its own field and Figure 21 is widely quoted in numerous papers and text-books (e. g.

    A. J. Bard, L. R. Faulkner, “Electrochemical Methods, fundamentals and Applications.” 1980. p.550, 551).
    The performance of silver oxide electrodes is knowng to be sensitive to the magnitude of the charging current (4). Upon

    chargin at 17 mA/cm~2 (Curve a, Figure 3), potential plateaux corresponding to
    2Ag+2OH~-→Ag_2O+H_2O+2e~-
    and
    Ag_2+4OH~-→Ag_2O_3+2H_2O+4e~-
    are observed prior to oxygen evolution (highest plateau). The potential decay curve displays three plateaux corresponding to

    the reverse reactions
    Ag_2O_3→A →Ag_2O→Ag
    In concentrated electrolyte, the cell resistance reflects primarily the resistance of the surface layer. Verification of this

    fact was achieved by measurement of the resistance during potential decay. The initial decay of Ag_2O_3 to A proceeds at

    low resistance in accordance with the relatively high conductance of these compounds Ag_2O_3, 2×10~2 Ω~(-1)cm~(-1); A ,

    10~(-1) Ω~(-1)cm~(-1)). The transformation of the surface layer from A to Ag_2O proceeded concurrently with an increase in

    resistance (Ag_2O3, 10~(-8) Ω~(-1)cm~(-1)). The resistance diminished upon discharge of Ag_2O to Ag. Rapid measurements of

    this type facilitate successfull evaluation of Ag battery characteristics.
    Complex plane spectra of iron oxide electrodes (s) were generated by continuous variation of measurement frequency during

    experiments with both illuminated and non-illuminated electlodes. Analysis of the curves (Figure 4) provided an equivalent

    circuit that explained the observed results. It was found that the internal resistance of the semiconducting oxide (R_(SC))

    diminished under illumination simultaneousry with an increase in space charge capacitance. The capacitance and resistance

    data obtained show promise toward routine evaluation of semiconducting materials and may facilitate optimization of

    photoelectrochemical devices.
    (This paper has been presented on 161st meeting of the Electrochemical Society, 1982, Montreal, Canada)

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