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Internal structure of the accumulation area of a glacier and the use of the term “foliation”: comments on the paper by M. Vallon, J.-R. Petit and B. Fahre

Published online by Cambridge University Press:  30 January 2017

M.J. Hambrey
M.J. Hambrey*
Affiliation:
Geologisches Institut und Geographisches Institut, Eidg. Technische Hochschule, Sonneggstrasse 5, CH-8006 Zürich, Switzerland
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Abstract

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Type
Correspondence
Information
Journal of Glaciology , Volume 18 , Issue 78 , 1977 , pp. 160
Copyright
Copyright © International Glaciological Society 1977

Sir,

In a recent paper, Reference Vallon, Vallon, Petit and FahreVallon and others (1976) described the internal structure and fabric of the accumulation area of the Vallée Blanche in the Massif du Mont Blanc as revealed by ice cores. Only a few studies of the internal structure of temperate glaciers have been made, hence these observations are of particular interest from the point of view of ice deformation.

The authors described much of the ice in the cores as “foliated" and concluded that “the foliation has a sedimentary, and not a tectonic origin”. Whilst not wishing to dispute the origin of the layering in their ice cores, I am unhappy about the use of the term “foliation" in the above sense. In geological literature, foliation by definition must be the result of deformation. For example, Reference Turner and WeissTurner and Weiss (1963, p. 28) defined it “by the metamorphically produced surfaces of discontinuity in deformed rocks”, and it includes such structures as cleavage and schistosity. Similarly, previous descriptions and definitions of foliation in ice imply that it is a secondary planar structure produced by flow or strain (e.g. Reference SharpSharp, 1954; Reference Allen, Allen, Kamb, Meier and SharpAllen and others, 1960; Reference MeierMeier, 1960; Reference TaylorTaylor, 1962; Reference RaganRagan, 1969). Texturally, it consists of intercalated layers of coarse bubbly, coarse clear and fine-grained ice (cf. Reference Allen, Allen, Kamb, Meier and SharpAllen and others, 1960). It seems, therefore, that the term “foliation" is best restricted to features of deformational origin. If a stratified structure is observed in glacier ice, why not call it simply stratification or sedimentary layering (e.g. Reference Grove, Clark and Lewis Grove, 1960; Reference RaganRagan, 1969)?

Although the continuity and regularity of individual layers is sometimes a distinctive feature of stratification in ice, it is often difficult to distinguish it from foliation; this is why there has been so much controversy for. well over 100 years concerning the origin of layered structures in glaciers. In some places one can see that an early layering (stratification) is cut by another structure (foliation); it is then clear that deformation produces the second structure. Sometimes, however, one can make conclusions on the origin of the layering only after considering the disposition of all structures and the probable flow conditions in a particular glacier. In some glaciers, one finds that foliation is parallel to the stratification, as observed by Reference RaganRagan (1969) in an Alaskan valley glacier and, more extensively, by the writer in Norwegian cirque glaciers (Reference HambreyHambrey, 1975) Deformation is also important in such instances, because shearing is believed to take place in the planes of the existing layers when the strain conditions aie favourable, i.e. the precise orientation of the foliation is controlled by a pre-existing planar anisotropy.

Following further work on ice structures in Swiss valley glaciers, it seems to me that deformation is generally great enough to destroy the original stratification at an early stage, and one may not be able to recognize it at all in the ablation area. Thus, structural and fabric analyses of cores taken at various positions on a longitudinal profile from the upper accumulation area to the ablation area should give most interesting information concerning progressive deformation, particularly if the orientation of the cores can be ascertained and if surface structures and strain conditions can be determined simultaneously. One hopes that such a study can be made in the not too distant future !

References

Allen, C.R. 1960 Structure of the lower Blue Glacier, Washington, [by]Allen, C. R. Kamb, W.B. ,Meier, M. F. ,Sharp, R. P. . Journal of Geology, Vol. 68, No. 6, p. 60125, map insert.Google Scholar
Grove, J.M. Clark, J.M. 1960 The bands and layers of Vesl–Skauibreen. (In Lewis , W.V., ed. Investigations on Norwegian cirque glaciers. London, Royal Geographical Society p. 1123. (R.G.S. Research Series, No. 4.))Google 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.Google Scholar
Meier, M.F. 1960 Mode of flow of Saskatchewan Glacier, Alberta, Canada. U.S. Geological Survey. Professional Paper 351.Google Scholar
Ragan, D.M. 1969 Structures at the base of an ice fall. Journal of Geology, Vol. 77, No. 6, p. 64767.CrossRefGoogle Scholar
Sharp, R.P. 1954 Glacier flow: a review. Bulletin of the Geological Society of America, Vol. 65, No. 9, p. 82138.Google Scholar
Taylor, L.D. 1962 Ice structures, Burroughs Glacier, south–east Alaska. Ohio State University. Institute of Polar Studies. Report No. 3.Google Scholar
Turner, F.J. Weiss, L.E. 1963 Structural analysis of metamorphic tectonites. New York, McGraw–Hill Book Co., Inc.Google Scholar
Vallon, M. 1976 Study of an ice core to the bedrock in the accumulation zone of an alpine glacier, byVallon, M. , Petit, J.–R.,Fahre, B. . Journal of Glaciology, Vol. 17, No. 75, p. 1328.CrossRefGoogle Scholar