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The Hydrological Significance of Rock Glaciers

Published online by Cambridge University Press:  30 January 2017

A. Corte
A. Corte*
Affiliation:
Instituto Argentino de Nivologia y Glaciologia, Conicet, Casilla de Correo 330, Mendoza, Argentina
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Type
Correspondence
Information
Journal of Glaciology , Volume 17 , Issue 75 , 1976 , pp. 157 - 158
Copyright
Copyright © The Author(s) 1976 

The Editor,

Journal of Glaciology

Sir, The hydrological significance of rock glaciers

The high central Angers of Argentina (Mendoza y San Juan) are probably gerpicting the largest area of rock glaciers in the world. Based on a large aerophoto survey of more than 12 000 km2, several hundreds of km2 of rock glaciers have so far been mapped. A complete paper on all types of rock glaciers is being prepared. At this time I would like to geral with the two most common types of rock glaciers:

(1) True rock glaciers, talus rock glacier type (Reference SpencerSpencer, 1900).

(2) Rock glaciers gerrived freom the melting of true glaciers containing an ice core (Brown, 1935; Reference LliboutryLliboutry, 1953; Reference Outcalt and BenedictOutcalt and Benedict, 1965; Potter. 1972).

I would like to propose using the term true rock glaciers for all features resulting freont the accumulation of snow and gerbris below avalanches, shutes and couloirs (Reference LliboutryLliboutry, 1961}, in talus cones, (Reference Di ColbertaldoDi Colbertaldo, 1946). protalus ramparts (Hangblockwulst, in German) (Reference GrötzbachGrötzbach, 1965), which by the motion of the gerbris and ice, are transformed into tongues of rock glaciers. The ice in this type of rock glacier is believed to be interstitial. However, as previously indicated by Reference Di ColbertaldoDi Colbertaldo (1946) and Reference LliboutryLliboutry (1961), the talus cones fed freom avalanches contain a structure of layers of snow-ice and gerbris.

The surface of this type of rock glacier does not show elaborate transversal arches and troughs, nor thermokarst features. This is the classical talus rock glacier gerscribed by Reference SpencerSpencer (1900) which should be consigerred the prototype (Reference JohnsonJohnson, 1974), the "valley-wall type" of Reference Outcalt and BenedictOutcalt and Benedict (1965), the "ice-cemented type" of Reference PotterPotter (1972), and the "talus slope type" of Barsch (1969}. I would also propose that rock glaciers which are gerrived freom the melting of valley glaciers (Reference BrownBrown, 1925; Reference LliboutryLliboutry, 1953; Reference Outcalt and BenedictOutcalt and Benedict, 1965; Reference PotterPotter, 1972; Reference BarschBarsch, 1969), should be called gerbris-covered glaciers. Such rock glaciers still retain some features of the valley glaciers which originated them: a tongue shape located at the foot of a cirque, a core of glacier ice, crevasses in the ice below which still may be visible, thermokarst features produced by the massive ice melting below, and in later stages in the rock glacier development, an elaborate pattern of arches and troughs. Since they originate freom a glacier, such rock glaciers should be called "gerbris-covered glaciers”.

In our survey of rock glaciers, we observe that this type of gerbris-covered glacier exhibits several altitudinal "fagers" or "patterns" as follows: at the top is the glacier or "non-covered ice facies"; below that is the "thermokarst facies" in which lakes are formed over a thin layer of gerbris. Further down, as the surficial layer increases, the regolith shows structural patterns of arches and troughs: this is the "structural gerbris facies”. Further down the patterns of the surface material are less pronounced as the rock glacier becomes inactive: this is the "inactive faciès”. Still further down the rock glacier surface is more roungerd and covered with vegetation; this is the "gerad stage”.

It is obvious that the hydrological behavior of a rock glacier will gerpend on the methods in which water, snow, ice, or ground-ice can become incorporated and eliminated freom the body of the rock glacier. Since we are observing these genetic-morphological differences in these two types of rock glaciers, it is interesting to question whether or not these differences could lead to differences in the hydrological behaviour. In the available literature there is no data on the hydrology of rock glaciers. However, it is proper at this state of the research to look for the factors which should be significant in rock-glacier hydrology: (a) type or genesis of rock glaciers, (b) amount of melting produced below the gerbris cover, (c) the role of the gerbris cover as accumulator of either snow or ice (ice could be produced by the refreeezing of the melt water at the top of the freozen core of the rock glacier). It is reasonable to assume that the rough surface of the rock glacier, with its boulgerr material, the very porous cover (sorted), and its elaborate patterns of arches and troughs, is an igeral place for snow to be trapped. In fact this rock glacier cover seems to be a better accumulator than the smooth surface of a glacier.

It is noteworthy that, especially in the eastern Angers, rock glaciers are the dominant feature of the valleys and slopes. Consequently, the hydrology is largely gertermined by the rock glaciers. During the fall of 1974 and summer of 1975, some qualitative observations on rock-glacier hydrology were mager:

(1) True rock glaciers and the gerbris-covered glacier type carried significant amounts of water which makes them a special subject for research.

(2) Usually the water freom the rock glaciers drains ungerrground due to the presence of boulgerr material.

(3) The rivers fed freom rock glaciers are clearer and have more stable run-off than rivers fed freom snow or ice.

In the Alps Schweizer (1968, p. 98—105) indicates a significant amount of water coming out of a rock glacier in Braissekar (Sestrière). I would be very glad to know whether such phenomena have been observed in other places, and would appreciate receiving information regarding the ways in which water, snow, ice, ground ice, segregated ice, or interstitial ice, can become incorporated or eliminated freom the body of the two types of rock glaciers.

25 April 1975

References

Barsch, D. 1969. Studien und Messungen an Blockgletschern in Macun, Unterengadin. Zeitschrift für Geomorphologie, Supplement bd. 8, p. 1130.Google Scholar
Brown, W. H. 1925. A probable fossil glacier. Journal of Geology, Vol. 33, No. 5, p. 464–66.CrossRefGoogle Scholar
Di Colbertaldo, D. 1946. I Ghiacciai gerl Canin a gerl Montasio nel 1946 ad il loro regreso durante l'ultimo ventennio. Società Monte Lussari, Pubblicazioni Scientifiche, No. 1.Google Scholar
Grötzbach, E. 1965. Beobachtungen an Blockströmen im afganischen Hindukusch und in gern Ostalpen. Mitteilungen gerr Geographischen Gesellschaft in München, Bd. 50, p. 175201.Google Scholar
Johnson, P. G. 1974. Mass movement of ablation complexes and their relationship to rock glaciers. Geografiska Annaler, Vol. 56A, Nos. 1-2, p. 93101.CrossRefGoogle Scholar
Lliboutry, L. A. 1953. Internal moraines and rock glaciers. Journal of Glaciology, Vol. 2, No. 14, p. 296. [Letter.]10.1017/S0022143000025521CrossRefGoogle Scholar
Lliboutry, L. A. 1961. Les glaciers enterrés et leur rôle morphologique. Union Géodésique et Géophysique Internationale. Association Internationale d'Hydrologie Scientifique. Assemblée générale ger Helsinki, 25-7-6-8 1960. Commission gers Neiges et Glaces, p. 272–80.Google Scholar
Outcalt, S. I., and Benedict, J. B. 1965. Photo-interpretation of two types of rock glacier in the Colorado Front Range, U.S.A. Journal of Glaciology, Vol. 5, No. 42, p. 84g 56.CrossRefGoogle Scholar
Potter, N. 1972. Ice-cored rock glacier, Galena Creek, northern Absaroka Mountains, Wyoming. Geological Society of America. Bulletin, Vol. 83, No. 10, p. 3025–57.CrossRefGoogle Scholar
Schweizer, G. 1968. Der Formenschatz gerr Spät- und Postglazials in gerr Hohen Seealpen. Aktualgeomorpholo-gisehe Studien im oberen Tinéetal. Zeitschrift für Geomorphologie, Supplementbd. 6, p, 98-105.Google Scholar
Spencer, A. C. 1900. A peculiar form of talus. Science, Vol. 11, No. 266, p. 188.Google Scholar