Hostname: page-component-cd9895bd7-gxg78 Total loading time: 0 Render date: 2024-12-28T02:21:53.525Z Has data issue: false hasContentIssue false

Origin of rock glaciers

Published online by Cambridge University Press:  30 January 2017

Rights & Permissions [Opens in a new window]

Abstract

Type
Correspondence
Copyright
Copyright © International Glaciological Society 1974

Sir,

I should like to add some of my own observations on Arapaho Rock Glacier to those presented recently (Reference BenedictBenedict, 1973; Reference CarraraCarrara, 1973).

Despite the general rejection of Reference HoweHowe’s (1909) original view of the formation of rock glaciers in the San Juan Mountains of Colorado, there seems to be little doubt that at least some rock-glacier material may be derived from rock falls or cliff falls. However, whether this material falls on top of an existing glacier or becomes a rock glacier by the addition of interstitial ice still seems to be a contentious issue (Reference WhalleyWhalley, 1974). There is considerable evidence showing that large-scale cliff-fall (>103 m3) events are important geomorphic occurrences in mountainous areas (Reference RappRapp, 1960; Reference KjartanssonKjartansson, 1967; Reference AbeleAbele, 1972). The way in which the debris accumulated on top of a glacier (as appears to be the case at Arapaho Rock Glacier) is important with respect to the past mass balance of the glacier.

As studies after the 1964 Alaskan earthquake have shown (Reference Bull and MarangunicBull and Marangunic, 1968; Reference PostPost, 1968), debris cover over a glacier can greatly modify its behaviour and this may be important in the formation of rock glaciers.

At Arapaho Rock Glacier, the cliff above the small Arapaho South Glacier and below South Arapaho Peak (Fig. 1) bears evidence of a cliff-fall scar. This can be seen from the difference in lichen cover across the cliff. Large vertical cracks and unstable blocks with a scanty (Gannett Peak age (Reference BenedictBenedict, 1968)) lichen cover can be seen within this area. It is suggested, therefore, that some of the Arapaho Rock Glacier debris came from these cliffs as a “one-shot” event. Further evidence can be seen in Figure 1. There is an area on the right of the rock glacier where the predominant block size is much greater than the remaining area. Examination in the field and with air-photograph enlargements bears this out. The lichen cover on most of the large blocks on the rock-glacier surface is of two kinds. Some surfaces have a relatively heavy cover of Rhizocarpon geographicum sp. and Lecanora thomsonii which has been cut across by breakage of the apparently original surface. Adjacent surfaces usually only have a very sparse cover of R. geographicum but somewhat more L. thomsonii. Though no detailed investigation could be undertaken, it appears that the heavy cover of lichen relates to the original cliff surface and the sparse areas to subsequent lichen colonization after the cliff fall, the latter being of probable Gannett Peak age.

Fig. 1. Arapaho Rock Glacier with the area of larger boulders on the surface delimited on the true right. Arapaho South (S) and North (N) Glaciers are marked together with South Arapaho Peak and the cliff from which the fall is thought to have occurred (C). (Photograph by Falcaon Air Maps, Denver, Colorado, 24 September 1963; 3120, negative 75 by courtesy of Dr D. D. MacPhail, NSF project GP-1484.)

The large size of the blocks on the surface in one area can also be directly compared with large blocks below steep rock buttresses in the surrounding area (Fig. 1). A Х 2 test showed that this is a highly significant correlation. Similar size distribution of blocks from cliff falls can be found in other parts of the world; they contrast with the size of debris which accumulates below gullies as a result of minor rock falls (Fig. 1). Though this evidence suggests that only a part of the rock-glacier debris may have come from a single, relatively large event, it does at least give an idea as to how rock-glacier material may build up.

Arapaho (north) Glacier (Reference Outcalt and MacPhailOutcalt and MacPhail, 1965) is the largest in the Colorado Front Range (c. 0.2 km2). The extent of ice traced below Arapaho Rock Glacier (Reference BenedictBenedict, 1973) shows that this glacier was once at least as extensive as the north glacier. The fact that none of the other rock glaciers in the Colorado Front Range appears to have a “one-shot” origin for much of their debris makes it possible that the original Arapaho South Glacier was greatly modified by the cliff fall.

These ideas tend to support a modified view of that proposed by Reference BenedictBenedict (1973): that Arapaho Rock Glacier at least was formed at a time of greater glacier extent than at present and that this may be related to a higher rate of debris production from cirque headwalls in the past.

The process of debris accumulation by shear-plane deformation as envisaged by Reference CarraraCarrara (1973) is a possibility, though investigations, e.g. Reference HookeHooke (1970), suggest a deforming zone rather than a plane. General observations in temperate glaciers have generally failed to show evidence of either shear planes or deforming zones bringing debris to the surface. The exception to this appears to be on thin retreating tongues where the winter “cold wave” can freeze material to the sole of the glacier. This debris is then brought to the surface very near (5–20 m) the ice margin. This process has also recently been suggested by Reference Boulton, Price and SugdenBoulton (1972). An accumulating thickness of debris would progressively restrict this mechanism so that its overall importance would be very limited.

22 November 1973

References

Abele, C 1972. Kinematik und Morphologie spät- und postglazialer Bergstürze in den Alpen. Zeitschrift für Geomorphologie, Neue Folge, Supplementbd. 14, p. 13849.Google Scholar
Benedict, J. B 1968. Recent glacial history of an alpine area in the Colorado Front Range, U.S.A. II. Dating the glacial deposits. Journal of Glaciology, Vol. 7, No. 49, p. 7787.CrossRefGoogle Scholar
Benedict, J. B 1973. Origin of rock glaciers. Journal of Glaciology, Vol. 12, No. 66, p. 52022. [Letter.]Google Scholar
Boulton, G. S 1972. The role of thermal régime in glacial sedimentation. (In Price, R. J, and Sugden, D. E, comp. Polar geomorphology. London, Institute of British Geographers, p. 119. (Institute of British Geographers. Special Publication No. 4.))Google Scholar
Bull, C. B. B, and Marangunic, C. D 1968. Glaciological effects of debris slide on Sherman Glacier. (In [U.S.] National Research Council. Division of Earth Sciences. Committee on the Alaska Earthquake. The great Alaska earthquake; hydrology. Part A. Washington, D.C., National Academy of Sciences, p. 30917. (Publication 1603.))Google Scholar
Carrara, P. E 1973. Transition from shear moraines to rock glaciers. Journal of Glaciology, Vol. 12, No. 64, p. 149. [Letter.]CrossRefGoogle Scholar
Hooke, R. L 1970. Morphology of the ice-sheet margin near Thule, Greenland. Journal of Glaciology, Vol. 9, No. 57, p. 30324.CrossRefGoogle Scholar
Howe, E 1909. Landslides in the San Juan Mountains, Colorado: including a consideration of their cause and their classification. U. S. Geological Survey. Professional Paper 67.CrossRefGoogle Scholar
Kjartansson, G 1967. The Steinsholtshlaup, central-south Iceland on January 15th, 1967. Jökull, Ár 17, p. 24963.Google Scholar
Outcalt, S. I, and MacPhail, D. D 1965. A survey of neoglaciation in the Front Range of Colorado. University of Colorado Studies. Series in Earth Sciences, No. 4.Google Scholar
Post, A. S 1968. Effects on glaciers. (In [U.S.] National Research Council. Division of Earth Sciences. Committee on the Alaska Earthquake. The great Alaska earthquake; hydrology. Part A. Washington, D.C., National Academy of Sciences, p. 266-308. (Publication 1603.))Google Scholar
Rapp, A 1960. Recent development of mountain slopes in Kärkevagge and surroundings, northern Scandinavia. Geografiska Annaler, Vol. 42, Nos. 2–3, p. 65200.Google Scholar
Whalley, W. B 1974. Rock glaciers and their formation as part of a glacier debris-transport system. Geographical Papers, Department of Geography, University of Reading, No. 24.Google Scholar
Figure 0

Fig. 1. Arapaho Rock Glacier with the area of larger boulders on the surface delimited on the true right. Arapaho South (S) and North (N) Glaciers are marked together with South Arapaho Peak and the cliff from which the fall is thought to have occurred (C). (Photograph by Falcaon Air Maps, Denver, Colorado, 24 September 1963; 3120, negative 75 by courtesy of Dr D. D. MacPhail, NSF project GP-1484.)