Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-23T12:32:57.242Z Has data issue: false hasContentIssue false

On electric polarization in ice*

Published online by Cambridge University Press:  30 January 2017

Walter Drost-Hansen*
Affiliation:
Institute of Marine Sciences, University of Miami, 1 Rickenbacker Causeway, Miami, Florida 33149, U.S.A.
Rights & Permissions [Opens in a new window]

Abstract

Type
Correspondence
Copyright
Copyright © International Glaciological Society 1969

The Editor,

Journal of Glaciology

Sir, On electric polarization in iceFootnote *

In a recent article by Reference ØstremØstrem (1967), attention is drawn to polarization effects observed in D.C. resistivity measurements on ice. In this connection, some earlier studies by Workman, Truby and the present author deserve mentioning. Together with Workman, Reference TrubyTruby (1953) observed remarkably pronounced polarization effects in D.C. measurements of the resistivity of both pure ice and ice frozen from various dilute solutions (such as 10−6 molar cesium fluoride and ammonia). The polarization was manifested as highly unexpected results in the D.C. measurements of the ice resistivity. Thus, the apparent resistance of the ice samples was initially found to depend on the direction of the applied potential, compared to the direction in which the ice had originally grown. Apparent “rectification ratios” of about 30000 were commonly observed. The crystals used in these studies were slowly grown at rates of a few (up to twenty) micrometers per second; often under very closely controlled conditions. The samples appeared by petrographic microscope examination and by standard X-ray diffraction techniques to be single crystals. The crystals were perfectly clear and free of bubbles, but did, in fact, possess a microstructure (Reference WorkmanWorkman, 1953; Reference TrubyTruby, 1955). The direction of highest resistance corresponded to a flow of protons toward the surface from which the ice grew, the rectification phenomenon described being extremely sensitive to the nature and amount of impurities in the solution frozen. In a study by Reference WorkmanWorkman and others (unpublished), it was observed that at −21°C, the conductivity of a fresh sample of ice, frozen from a 10−6 molar cesium fluoride solution is about 2×10−9 Ω −1 cm−1. However, the apparent conductivity of the ice depended on the potential difference across the sample. Figure 1 shows in a somewhat schematic fashion, the conductance versus field strength. This curve shows a distinct hysteresis loop, although attempts were made to minimize transient effects by allowing the current in each measurement to pass through the sample for about twenty minutes. It was found that this procedure resulted in some semblance of steady-state behavior. As can be seen from the graph, in the case described a 600000-fold change in resistance was observed, while in other cases, “rectification ratios” of 10+5 were observed. The resistance of “pure ice” was less sensitive to variations in field strength, by three to four orders of magnitude, than the resistance of ice frozen from dilute solutions containing cesium fluoride. It might be mentioned in passing that fields of 60000 V cm−1 could be applied without breakdown. Furthermore, the observed rectifying properties appeared to vanish at low frequencies, being approximately half at 60 Hz and almost completely eliminated at 200 Hz.

Fig. 1. Conductivity versus applied field strength for ice frozen from 10−6 molar cesium fluoride solution. Positive values of field strength correspond to flow of protons toward original ice-metal interface from which the ice was frozen.

At the time of the original measurements, it was thought that the rectification observed was associated with the microstructure of ice (Reference TrubyTruby, 1955; Reference Gentile and Drost-HansenGentile and Drost-Hansen, 1956; see also Reference Drost-HansenDrost-Hansen, 1967) and an electronic conduction mechanism. Subsequent study (Reference WorkmanWorkman and others, 1954) demonstrated that the conduction was entirely protonic (or, at least, that the discharge phenomena at the ice-metal interfaces was protonic). When it was recognized that the conduction was by protons rather than electronic, the question of electrode polarization was re-examined and the previously suspected “bulk rectification” proved not to be real. In this connection, it should be noted that many measurements were made with four-electrode configurations. It is speculated that even with the probe electrodes used in the four-electrode configuration, electrodepolarization effects may occur in the measurements. Electrometers and electrostatic voltmeters with very high input impedances (10+14 Ω or higher) were used, but even so, a certain amount of polarization will occur due to the displacement current necessary to bring the wires and the electrometer up to the observed potential. Workman and Truby (unpublished) and further studies by Carlin (unpublished), working with the present author, have shown that a pre-treatment of the platinum disk electrodes, commonly used in these ice studies, may play a dominant role in determining the interfacial resistive properties. Thus, by electrolysis in dilute solutions, prior to freezing the electrodes onto the ice sample, it was possible to change the “sense of direction” of the rectification phenomenon by either depositing a layer of hydrogen or a layer of oxygen on the electrodes. Thus, the rectification was made to depend on the electrolytic pretreatment rather than the direction of growth of the ice. Similar results were also found by Carlin using gold, copper, nickel, aluminum and carbon electrodes.

In summary, the author wishes to point to the dangers of electrode polarization phenomena in all d.c. measurements on ice (whether in naturally occurring ice or ice frozen in the laboratory) and the subsequent difficulties in ascribing unequivocally any observed, anomalous behavior to the structure and properties of the bulk ice. At the same time, a real effect may possibly exist due to partial charge accumulation effects at the interfaces between the microstructural units in the ice. Since the microstructure can be eliminated by increasing the electrolyte concentration, it is expected that the polarization effects may diminish or disappear at relatively low concentrations of electrolyte, say 10−3 or 10−4 molar. In general, d.c. conductivity is probably of limited use only for characterizing ice samples and a.c. measurements are generally to be preferred. Reference CampCamp and others (1967) have recently published a careful study of the electrical conduction in ice which may serve as a model for experimental studies of conductivity in protonic semi-conduction. See also the recent review article by Reference Gross and GouldGross (1968).

This note was prepared in connection with the author’s current research on ice, presently supported by the Office of Saline Water.

Walter Drost-Hansen

Institute of Marine Sciences, University of Miami, 1 Rickenbacker Causeway, Miami, Florida 33149, U.S.A. 3 June 1968

Footnotes

* Contribution No. 979 from the Institute of Marine Sciences, University of Miami.

References

Camp, P. R., and others. 1967. Electrical conduction in ice, by P. R. Camp, W. Kiszenick and D. A. Arnold. U.S. Cold Regions Research and Engineering Laboratory, Research Report No. 198.Google Scholar
Carlin, J. Unpublished. The dependence of measured charge separation upon the nature and polarization of the base during freezing of dilute aqueous solutions. [M.S. thesis, New Mexico Institute of Mining and Technology, 1956.]Google Scholar
Drost-Hansen, W. 1967. The water-ice interface as seen from the liquid side. Journal of Colloid and Interface Science, Vol. 25, No. 2, p. 13160.CrossRefGoogle Scholar
Gentile, A. L. Drost-Hansen, W. 1956. On the origin of the microstructure in ice. Naturwissenschaften. 43 Jahrg., Ht. 12, p. 27475.Google Scholar
Gross, G. W. 1968. Some effects of trace inorganics on the ice/water system. (In Gould, R. F., ed. Trace inorganics in water. Washington, D. C., American Chemical Society, p. 2797. (American Chemical Society. Advances in Chemistry Series, Vol. 73.))Google Scholar
Østrem, G. 1967. Laboratory measurements of the resistivity of ice. Journal of Glaciology, Vol. 6, No. 47, p. 64350.Google Scholar
Truby, F. K. 1953. Some electrical hysteresis properties of ice. Physical Review, Ser. 2, Vol. 92, No. 2, p. 54344.Google Scholar
Truby, F. K. 1955. Hexagonal microstructure of ice crystals grown from the melt. Journal of Applied Physics.Vol. 26, No. 12, p. 141620.CrossRefGoogle Scholar
Workman, E. J. 1953. The cellular nature of ice crystals. Physical Review, Ser. 2, Vol. 92. No. 2, p. 544.Google Scholar
Workman, E. J. and others. 1954. Electrical conduction in halide-contaminated ice, [by] E. J. Workman, F. K. Truby and W. Drost-Hansen. Physical Review, Ser. 2, Vol. 94, No. 4, p. 1073.Google Scholar
Workman, E. J. Truby, F. K. Unpublished. The electrical properties of pure and fluoride-contaminated ice. [Produced for New Mexico Institute of Mining and Technology, 1955.]Google Scholar
Workman, E. J., and others. Unpublished. The electrical and mechanical properties of ice, by E. J. Workman, F. K. Truby and W. Drost-Hansen. [Produced for New Mexico Institute of Mining and Technology, 1955.]Google Scholar
Figure 0

Fig. 1. Conductivity versus applied field strength for ice frozen from 10−6 molar cesium fluoride solution. Positive values of field strength correspond to flow of protons toward original ice-metal interface from which the ice was frozen.