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Origin of foliation in glaciers: comments on a paper by R. L. Hooke and P. J. Hudleston

Published online by Cambridge University Press:  30 January 2017

M. J. Hambrey*
Affiliation:
Department of Geology, Sedgwick Museum, Cambridge CB2 3EQ, England
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Abstract

Type
Correspondence
Copyright
Copyright © International Glaciological Society 1979

Sir,

The origin of foliation in glaciers has occupied the minds of glaciologists and geologists for over 150 years, yet there is still argument as to how the structure actually develops. The controversy as to whether foliation was a primary or a secondary structure, which raged periodically until the 1950’s, finally seemed to have been settled in favour of the latter following detailed work on glaciers by, for example, Reference Schwarzacher and UntersteinerSchwarzacher and Untersteincr (1953), Reference MeierMeier (1960), and Reference Allen, Allen, Kamb, Meier and Sharp.Allen and others (1960). A thought-provoking paper by Reference Hooke and HudlestonHooke and Hudleston (1978) questions these later conclusions by suggesting that bubbles and debris in glaciers are unable to migrate sufficiently rapidly to be responsible for the alternating layers of bubbly and clear ice, or dirty and clean ice which constitute foliation, and that the structure is inherited from earlier layering, such as stratification, crevasse fillings, or debris-layers frozen to the glacier bed.

The authors are right to point out that the relationship of foliation to earlier layering is critically important. I have gradually come to the same conclusion independently, first following detailed work on Charles Rabots Bre, Norway (Reference HambreyHambrey, 1975, Reference Hambrey1976[b]) where the foliation in part is parallel to stratification, then later on Griesgletscher, Switzerland (Reference Hambrey and MilnesHambrey and Milnes, 1977) and on the White Glacier, Axel Heiberg Island (Reference Hambrey and MüllerHambrey and Müller, 1978) where the foliation is parallel to rotated or transposed crevasse traces and other structures. I would not, however, go as far as to say that all foliations are derived from earlier layering, and would dispute the assertion that bubbles and debris cannot migrate in glacier ice; the field evidence often suggests otherwise. For example, the amount and size of debris often entrained parallel to vertical foliation in marginal areas of glaciers is often too great to be explained in terms of wind-blown debris being deposited on the ablation surface and subsequently incorporated in the stratification. It is also difficult to envisage foliation representing strongly rotated and deformed crevasse fillings–sometimes no crevasses are present in the expected areas, so the only conclusion I can come to is that by some process we do not understand, shear in marginal ice near the glacier surface enables debris to be brought down from a moraine-covered surface. Furthermore, longitudinal marginal foliation very often is not parallel to the sides when observed in three dimensions. Although the surface trace of foliation may be parallel to the sides, the structure is usually vertical even where the valley sides are gently inclined, and this would not be so if it were merely rotated stratification. A two-dimensional analysis of strain reveals a fairly simple relationship with such foliation, as discussed below, but the three-dimensional picture is bound to be more complex, and even if obtainable, it would probably be difficult to interpret.

Another objection I have concerns the distribution of bubbles. In stratified ice, the coarse bubbly variety, representing the original accumulations of snow, generally makes up over 80% of the total ice, whereas clear ice, representing frozen lenses or layers of melt water is subordinate. Yet in foliation, clear ice usually forms a much greater proportion of the total, often 50% or more. The question arises: “Where have all the bubbles gone?” I suggest that recrystallization has played a major part in eliminating bubbles, but precisely how I cannot explain. Possibly, fine-grained ice layers, developed by the process of mylonitization due to localized, intensified shear, “absorb” them, since they have the appearance of being extremely bubbly and firn-like. Obviously, much work is needed on the behaviour of debris and bubble-layered ice in deforming ice.

A second important point made by Hooke and Hudleston is that inhomogeneities are modified by strain to produce foliation, so that at the very great total strains expected in glaciers they have been flattened, stretched, and rotated to give a layered structure roughly perpendicular to the direction of maximum total shortening. The validity of this statement is shown by data we have obtained from Griesgletscher (Reference Hambrey and MüllerHambrey and Milnes, 1977). On this glacier the dominant structure is an arcuate foliation originating in a small ice fall. (We prefer to use the term “arcuate” as opposed to “transverse” as it more accurately expresses the geometry of the structure.) The strain history of marginal ice is very different from that of ice in the middle of the glacier. If one analyses the change in shape of a circle near the margin of the glacier, we find that it deforms into an ellipse orientated initially at a moderate angle to the foliation, which here is longitudinal. With progressive deformation, the ellipse rotates towards approximate parallelism with the structure (non-coaxial strain), and becomes extremely elongated. In contrast, in the centre of the glacier, a circle deforms into an ellipse with its long axis parallel to the foliation, here transverse, as it passes through the ice fall (coaxial strain), after which it changes very little in shape or orientation with respect to the structure. The foliation is best developed in zones that have undergone the greatest strain, and it bears very few traces of earlier structural inhomogeneities. As Hooke and Hudleston suggest, they have been stretched and rotated into the plane of maximum total shortening, parallel to the foliation.

Having thus far to some extent agreed with Hooke and Hudleston’s conclusions, I would now like to turn to a somewhat different matter over which our views are at variance, namely concerning the mode of incorporation of debris into a glacier from its bed. This is a controversial topic which should be clarified since many glacial geologists regard the incorporation of debris from the bed by shearing as a fact, without being aware that some glaciologists regard the process as mechanically unlikely (e.g. Reference WeertmanWeertman, 1961; Reference HookeHooke, 1968). Hooke and Hudleston (p. 22) cite me as misquoting Reference SwinzowSwinzow (1962) and Reference WeertmanWeertman (1968), a statement with which I must partially disagree (this, incidentally, in a paper not listed in their references (Reference HambreyHambrey, 1976[a]). The offending sentence is that “several workers have suggested that debris may be incorporated into glacier ice by shear (thrust) planes extending from the bed”. Whilst Swinzow, referring to moraines at the margin of the Greenland ice sheet, does say that the question as to how debris is incorporated is somewhat separate from the processes discussed in his paper (as mentioned by Hooke and Hudleston), he does, nevertheless write as part of his hypothesis that “a flow plane loaded with bottom material constitutes a shear plane” (p. 228). Elsewhere (p. 226–27) he says that in the early stages of the development of these moraines “ice below the silt band moves slower than the ice above or in some cases does not move at all”. I do not believe that my statement misrepresents Swinzow. I do, however, extend my apologies to Professor Weertman for implying that he suggested that debris could be incorporated by shear. In fact he was referring to earlier ideas and went on to draw attention to the fact that the mechanism could only occur in regions of compression, if at all. Furthermore he raised fundamental objections to the shear hypothesis in general. I am grateful to Drs Hooke and Hudleston for pointing this out. A point I might raise here is that my reference to dirt-bearing foliation in Charles Rabots Bre concerned vertical, longitudinal foliation exposed at the surface. This is a rather different problem to the incorporation of moraine from the glacier bed and entrainment along shear planes being discussed in this section of their paper. Even so, I disagree with the authors and maintain that debris can be incorporated by a mechanism that does involve shear along discrete planes–not by rolling along the planes but by overriding of debris-laden basal ice along surfaces representing favourably orientated planes of weakness, e.g. crevasse traces. However, the debris may originally have been frozen to the bed by Reference WeertmanWeertman’s (1961) mechanism. We have recently argued the case for the shear process with reference to sub-polar glaciers on Axel Heiberg Island (Reference Hooke and HudlestonHambrey and Müller, 1978), hence there is no need to repeat the arguments here. I might add that structural evidence in many cases suggests displacements of from a few millimetres to a metre or more in both cold and temperate glaciers. I would like to mention two more contrasting examples. First I have noted on Griesgletscher the displacement of a crevasse trace by 20 mm along a plane parallel to longitudinal foliation. Secondly, at the snout of Glacier de Tsijiore Nouve, Switzerland debris evidently is incorporated along low-angle planes parallel to a rotated arcuate foliation, a structure initially of vertical attitude formed in an ice fall, and these planes displace by up to 1 m slightly-rotated crevasse traces. When these crevasse traces are rotated further to a medium angle, they themselves become reactivated as shear planes and cut a later set of crevasse traces by a similar amount. I am convinced that discrete shearing is a widespread phenomenon, but develops on pre-existing planes of weakness. I do not think it can be explained away mathematically because ice is structurally inhomogeneous and no set of equations can take the inhomogeneities into account, but I would be interested to hear of other explanations for the features noted above. I would qualify these statements and say that the amount of debris involved is generally small and normally confined to the snouts of active glaciers.

In conclusion, despite my objections raised above, I believe Hooke and Hudleston have provided us with an excellent review of the foliation problem and have enabled us to focus our attention on those aspects in need of further research.

M. J. Hambrey

Department of Geology,

Sedgwick Museum,

Cambridge CB2 3EQ, England

29 December 1978

References

Allen, C. R., and others 1960. Structure of the lower Blue Glacier, Washington, [by] Allen, C. R. Kamb, W. B. Meier, M. F. and Sharp., R. P. Journal of Geology, Vol. 68, No. 6, p. 60125.CrossRefGoogle Scholar
Hambrey, M. J. 1975. The origin of foliation in glaciers: evidence from some Norwegian examples. Journal of Glaciology, Vol. 14, No. 70, p. 18185.CrossRefGoogle Scholar
Hambrey, M. J. 1976[a]. Debris, bubble, and crystal fabric characteristics of foliated glacier ice, Charles Rabots Bre, Okstindan, Norway. Arctic and Alpine Research, Vol. 8, No. 1, p. 4960.CrossRefGoogle Scholar
Hambrey, M. J. 1976[b]. Structure of the glacier Charles Rabots Bre, Norway. Geological Society of America. Bulletin, Vol. 87, No. 11, p. 162937.2.0.CO;2>CrossRefGoogle Scholar
Hambrey, M. J., and Milnes, A. G. 1977. Structural geology of an Alpine glacier (Griesgletscher, Valais, Switzerland). Eclogae Geological Helvetiae, Vol. 70, No, 3, p. 66784.Google Scholar
Hambrey, M. J., and Müller, F. 1978. Structures and ice deformation in the White Glacier, Axel Heiberg Island, Northwest Territories, Canada. Journal of Glaciology, Vol. 20, No. 82, p. 4166.CrossRefGoogle Scholar
Hooke, R. L. 1968. Comments on “The formation of shear moraines: an example from south Victoria Land, Antarctica”. Journal of Glaciology, Vol. 7, No. 50, p. 35152. [Letter.]CrossRefGoogle Scholar
Hooke, R. L., and Hudleston, P. J. 1978. Origin of foliation in glaciers. Journal of Glaciology, Vol. 20, No. 83, p. 28599.CrossRefGoogle Scholar
Meier, M. F. 1960. Mode of flow of Saskatchewan Glacier, Alberta, Canada. U.S. Geological Survey. Professional Paper 351.Google Scholar
Schwarzacher, W., and Untersteiner, N. 1953. Zum Problem der Bänderung des Glelschereises. Sitzungsberichte der Österrdchischen Akademie der Wissenschaften. Mathematisch-naturwissenschaftliche Klasse, Abt. 2A, Bd. 162, Ht. 1–4, p. 11145.Google Scholar
Swinzow, G. K. 1962. Investigation of shear zones in the ice sheet margin, Thule area, Greenland. Journal of Glaciology, Vol. 4, No. 32, p. 21529.Google Scholar
Weertman, J. 1961. Mechanism for the formation of inner moraines found near the edge of cold ice caps and ice sheets. Journal of Glaciology, Vol. 3, No. 30, p. 96578.CrossRefGoogle Scholar
Weertman, J. 1968. Diffusion law for the dispersion of hard particles in an ice matrix that undergoes simple shear deformation. Journal of Glaciology, Vol. 7, No. 50, p. 16165.CrossRefGoogle Scholar