IT has been reported (Reference Knight, DeVries and OolmanKnight and others, 1984, 1988) that the antifreeze glycopeptides (AFGPs) which protect Antarctic fish from freezing also inhibit recrystallization and grain-boundary migration in ice, even at concentrations as low as 10⁻⁷gg⁻¹ (c. 10⁻¹⁰ M). Recrystallization is involved in the creep of polycrystalline ice and the process of creep may therefore be influenced by the presence of AFGPs. Single ice crystals deform easily by slip on the basal (0001) plane; a polycrystalline aggregate cannot deform using only this easy-glide mechanism but needs a further process such as grain-boundary migration or recrystallization. Thus, unlike single crystals, polycrystalline ice initially has a creep rate which decreases with time as deformation of those grains oriented for slip under the applied stress is inhibited by the effect of other grains oriented so that the shear stress on the slip plane is small. This is the explanation given for the initial decelerating or transient component of the typical creep curve of polycrystalline ice. It is followed by a secondary, or steady creep attributed to some recovery mechanism and at larger strains, by an accelerating or tertiary creep associated with the dynamic recrystallization of the ice. This is the explanation given (Glen, 1955) for the typical creep curve of polycrystalline ice. Thus, if AFGPs inhibit recrystallization, they should also suppress the tertiary creep and perhaps slow down the earlier stages if significant grain-boundary migration is involved in them. This short note reports the first tests to investigate this phenomenon.

The proteins used were a mixture of AFGPs 1–5 isolated from Antarctic fish by A.L. DeVries. Cylindrical specimens of randomly oriented polycrystalline ice with and without the AFGPs were prepared by first loosely filling moulds with frost particles from the cold-room cooling tubes. The moulds were then filled with ice-cold water (with or without the additive) and then frozen at c. −15°C. The AFGP solutions used had a concentration of c. 10⁻⁷gg⁻¹.

The creep-testing machine used was similar to that used by Reference Homer and GlenHomer and Glen (1978). The stress was supplied by weights and the strain was measured using a displacement transducer. The creep tests were all performed at −1.5°C Three stress levels were used: 570, 860, and 1210 kPa. The resultant creep curves are plotted in Figure 1 in the form of strain-rate plotted logarithmically against strain. In this plot the transient primary creep is represented by the descending curve on the left of the plot. Continuing steady-state creep gives a horizontal line, while tertiary creep gives a rising curve on the right. In no case did a specimen containing the antifreeze protein show tertiary creep. In all pure ice samples, a minimum creep rate was reached at about the same strain (2.5–3%) and was followed by a rising, tertiary, creep rate. For a given stress and strain, the strain-rates of the samples containing AFGPs were significantly less even during primary creep.

Since it is known (Reference GlenGlen, 1955; Reference Gow and SheehyGow and Sheehy, 1987) that pure ice recrystallizes both during deformation and after deformation has ceased, and since this recrystallization produces new grains with an orientation fabric more favourably oriented for deformation, it has been suggested (Reference GlenGlen, 1955; Reference Gao and JackaGao and Jacka, 1987) that the tertiary acceleration is due to this recrystallization. The present experiments are consistent with this view since the specimens containing AFGPs, which have previously been shown to have their recrystallization inhibited, have now been shown not to exhibit the tertiary acceleration.

Fig. 1. Strain-rale of polycrystalline ice plotted against strain in constant-load creep tests at −1.5°C.□ 1210 kPa, without AFGPs; ■ 1210 kPa, with AFGPs; Δ 560 kPa, without AFGPs: ▲ 860 kPa, with AFGPs; ○ 570 kPa, without AFGPs; ● 570 kPa, with AFGPs. Only selected points are plotted. Note that all the specimens with AFGPs settle to a steady secondary creep rate with no indication of the acceleration which is seen in all the undoped specimens.

Clearly, it would be desirable to confirm this conclusion by appropriate studies on the grain-size of specimens before and after testing, and it is hoped to undertake such tests in the future. The mechanism by which AFGPs prevent grain-boundary motion is not entirely clear. It is probably related to the similar inhibition effect it has on crystal growth, a property of more significance for the Antarctic fish (Reference DeVriesDeVries, 1984). It is not due to concentration of all the AFGPs at grain boundaries, since Reference Gross, Gutjahr and CaylorGross and others (1987) have shown that AFGPs are the most highly soluble of all known impurities in ice; however, any concentration imbalance between the bulk ice and the grain boundary could retard boundary migration. The problem of how the AFGPs inhibit growth of ice crystals from the melt has been investigated by Reference Wilson and DeVriesWilson and DeVries (1987); a preliminary report of the present work was made as a comment on that paper and is printed at the end of its abstract.

We should like to thank Dr C.A. Knight for drawing to our attention the possibility of an effect on mechanical properties, and Professor A.L. DeVries for supplying the antifreeze glycopeptides.