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A Supraglacial Extension of an Ice-Dammed Lake, Tunsbergdalsbreen, Norway

Published online by Cambridge University Press:  30 January 2017

Philip J. Howarth*
Affiliation:
Department of Geography, University of Glasgow, Glasgow, Scotland
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Abstract

Observations on Tunsbergdalsbreen show that an ice-dammed lake, Store Brimkjelen, overflowed on to the surface of the glacier. The lake lifted a section of the glacier and formed a long irregular crevasse along the line of dislocation.

Résumé

Résumé

Extension supra-glaciaire d’un lac d’un barrage de glace, Tunsbergdalsbre, Norvège. Des observations faites au Tunsbergdalsbre montrent qu’un lac de barrage glaciaire, Store Brimkjelen, inonda la surface du glacier. Le lac souleva une partie du glacier et forma une longue crevasse irrégulière le long de la ligne de dislocation.

Zusammenfassng

Zusammenfassng

Ausdehnung eines Eisstausees am Tunsbergdalsbre, Norwegen, auf das Gletschereis. Beobachtungen am Tunsbergdalsbre zeigen, dass ein Eisstausee, der Store Brimkjelen, die Gletscheroberfläche überflutet hat. Der See hat einen Teil des Gletschers hochgehoben; an der Hebungslinie bildete sich cine lange unregelmässige Gletscherspalte.

Type
Research Article
Copyright
Copyright © International Glaciological Society 1968

Introduction

Between 1956 and 1964, the Brathay Exploration Group, in consultation with Dr J. F. Nye, undertook a programme of glaciological investigations on Tunsbergdalsbreen, the largest outlet glacier in Norway. As part of this project, the author studied an ice-dammed lake, Store Brimkjelen, situated on the western margin of the glacier. This paper considers the development of a supraglacial extension of the lake that was formed in 1962.

Tunsbergdalsbreen and Store Brimkjelen

Tunsbergdalsbreen (lat. 61° 35′ N., long. 7° 05′ E.) flows south from the ice cap of Jostedalsbreen, located between the Nordfjord and the Sognefjord on the west coast of Norway. Its valley section, from the edge of the ice cap to the snout, is approximately 13 km long, and over this distance its width varies between 1 000 m and 1 700 m. The snout of the glacier rests on a rock bar and the main outlet stream occupies a gorge cut through the rock bar.

Brimkjelen forms a branch valley of Tunsbergdalsbreen, the sides and headwall of which are extremely steep. The valley is situated on the west side of Tunsbergdalsbreen below a low ice fall, a distance of 4 500 metres from the snout of the glacier. Tunsbergdalsbreen widens as Brimkjelen joins the main valley, and ice from the western side of the glacier turns to flow towards the side valley. The ice ends in a steep cliff, which produces the dam for the lake. An indication of the ice flow towards the side valley is given by a medial moraine which curves from south through to south-west to end in the crevassing close to the ice cliff (Fig. 1).

Fig. 1. The location of Brimkjelen. The positions of the supraglacial extension of the lake and the irregular crevasse have been superimposed on the map produced by Reference KickKick (1966).

The Development of Store Brimkjelen

The retreat of the glacier that occupied Brimkjelen has been comparatively rapid. In 1903 it was still in contact with Tunsbergdalsbreen (Reference RekstadRekstad, 1911, p. 15). By 1937 it had retreated to the head of the lake then occupying the valley (Reference PillewizerPillewizer, 1952), and all that remains at present is a narrow glacier tongue suspended above the headwall of the valley.

Records of outbursts from the lake have been well documented. Every year between 1896 and 1900, and again in 1903, floods occurred in the Leirdal river draining from the glacier (Reference LiestølLiestøl, 1956, p. 132). In 1900 and 1903, Reference RekstadRekstad (1901, Reference Rekstad1904) visited the glacier to try to determine the cause of the flooding.

The flood of 1900 took place on 6 August. When Rekstad visited the glacier in September, he found that the surface of the ice in the inner part of Brimkjelen was approximately 100 m lower than the main glacier of Tunsbergdalsbreen and was badly broken up (Reference RekstadRekstad, 1901, p. 83). He suggested that the ice in Brimkjelen had sunk into the bottom of the valley after a lake, formed beneath the glacier, had drained. As there was no evidence that the water had flowed over the surface of the glacier, he considered that the lake must have drained through a tunnel underneath Tunsbergdalsbreen (Reference RekstadRekstad, 1901, p. 85).

In 1903, a severe flood occurred on 22–23 August which destroyed a bridge over the Leirdal river (Reference RekstadRekstad, 1904, p. 1). Rekstad visited Tunsbergdalsbreen in September of that year and again found that in the inner part of Brimkjelen, the ice had sunk into the bottom of the valley. On this visit, he also observed that a large crevasse had been formed where the glacier from Brimkjelen joined with Tunsbergdalsbreen. At the crevasse, the surface of Tunsbergdalsbreen was 5 to 1 o m higher than the ice flowing from Brimkjelen Reference Rekstad(Rekstad, 1904, p. 2–3).

The effects of a severe flood in 1926 were observed by Reference IngstadIngstad (1927). Gravel and boulders were carried into the Jostedal (a distance of approximately 14 km from the snout of the glacier) causing the river in that valley to be dammed and a lake to be formed. Ingstad reckoned that 25 to 30 million cubic metres of water must have been released from Brimkjelen during this flood.

The ice-dammed lake was mapped for the first time in 1937 by Finsterwalder and others as part of a photogrammetric survey of the glacier (Reference PillewizerPillewizer, 1952). The survey was repeated by Kick and Dorrer in 1961, at which time the lake did not occupy the valley, and it was calculated that in 1937, Store Brimkjelen must have held 19·2 million cubic metres of water (Reference KickKick, 1966, p. 9).

A map of the glacier at a scale of 1: 20 000 was also published in 1966 by the Hydrologisk Avdeling of Norges Vassdrags- og Elekrisitetsvesen (Reference Otnes and ØstremOtnes and Østrem, 1967). The map of the lower half of the glacier, based on vertical aerial photography flown in 1955, provides additional information on the downwastage of the glacier surface.

Since 1937, and perhaps earlier, the ice cliff has maintained virtually the same position in relation to the valley of Brimkjelen that it has today, forward movement of the glacier being balanced by collapse from the ice cliff. In spite of this, the glacier has shown general down-wastage of its surface, concurrent with the retreat of its snout. On the map of Tunsbergdalsbreen produced by Reference KickKick (1966), it can be seen that the ice surface in the area of Brimkjelen has been lowered by approximately 50 m in 24 years. This figure amounts to almost Go m close to the northern wall of Brimkjelen, the increased ablation probably being due to the effect of heat from the valley side. The result has been gradually to increase the angle of slope of the glacier surface close to the northern wall of Brimkjelen and to form a depression running east - west between the ice surface and the valley side.

A topographic map of Jostedalen, at a scale of 1: 50 000 and based on vertical aerial photography flown in 1966, is to be published soon by the Norges Geografiske Oppmáling. A blue-print of this map, which includes almost the entire area of Tunsbergdalsbreen, has been kindly sent to the author by Dr Østrem. On the map, the Boo m contour in the area of Brimkjelen clearly indicates the depression formed between the glacier and the valley side. This depression was occupied by a supraglacial extension of Store Brimkjelen, formed in 1962.

Observations in 1962

In August 1962, the floor and sides of Brimkjelen were filled with blocks of ice. The lake which had deposited these icebergs had drained, although water could be seen in the very bottom of the valley amongst the icebergs close to the ice cliff. The upper limit of deposition of icebergs formed a very regular line, clearly indicating the maximum height of the lake (Fig. 2). From the contours on the map produced by Reference KickKick (1966), it is estimated that the height of the lake surface was approximately 815 m a.s.l.

Fig. 2. Brimkjelen from the northern side of the valley. The height of the lake which occupied the valley is indicated by the upper limit of deposition of icebergs. Icebergs deposited on the surface of the glacier by the supraglacial extension of the lake can be seen at the bottom of the photograph. Part of the irregular crevasse runs down the centre of the medial moraine at the left side of the photograph.

As well as filling part of the valley, it was apparent that the water had overflowed on to the surface of the glacier. The supraglacial extension of the lake had occupied the depression between the surface of the glacier and the valley side (Fig. 1). The rise of the ice surface away from the valley side had prevented drainage from the lake over the surface of the glacier.

Large blocks of clean, white ice, some at least 5 m high, had been deposited on the surface of the glacier. The largest blocks can be seen at the bottom of Figure 2, close to the edge of the glacier. A number of the smaller blocks of ice had formed “glacier tables” by protecting the underlying pedestal of surface ice from melting (Fig. 3). Whether the height of the pedestal represents the ablation that had occurred after the lake had drained, it is impossible to say, for the ice blocks could easily have slipped more than once. From the contours on the map produced by Reference KickKick (1966), however, the depression at the edge of the glacier would easily have permitted blocks of ice to be floated on to the surface of the glacier, assuming the height of the lake surface to have been approximately 815 m.

Fig. 3. “Glacier tables” formed by small icebergs of white ice deposited on the glacier suface by the lake.

In addition to the ice blocks, the surface of the glacier indicated the former presence of water, areas of it having been washed clean of the finer debris. The ice in these parts had a crenulated micro-relief, similar to that produced in areas of small, shallow, slow-flowing supra-glacial streams. It suggests that perhaps the water had only recently vacated this part of the ice.

The most important effect of the water was to cause bodily movement of the glacier. A whole section of the glacier appeared to have been lifted by the lake, and an irregular crevasse (Figs. 1 and 4) indicated the line of dislocation, which resulted from this movement. The crevasse ran from the base of the ice fall (in the middle distance of Figure 4) to the ice shelf above Brimkjelen, where it was at least 200 m from the side of the valley. The normal crevasses in this part of the glacier are longitudinal, meeting the valley side at angles of at least 60°. In contrast to this, the irregular line of dislocation ran almost at right angles to the normal crevasse pattern. Dislocation of the ice had also occurred at the edge of the glacier. Here, crevasses running parallel to the side of the valley were formed, and cracks were developed in snow gullies extending on to the edge of the ice. There was slumping of snow and moraine on to the surface of the glacier.

Fig. 4. Part of the irregular crevasse extending to the base of the low ice fall in the middle distance. This crevasse runs at right angles to the normal direction of crevassing in this area. Note the debris of the medial moraine on the surface of the glacier.

Upward movement of the ice had occurred in the area where the supraglacial lake had occupied the depression between the ice surface and the valley side, but in what manner the lifting of this section of the glacier took place could not be determined. It is possible that the whole section was raised as a single unit. Alternatively, either the crevasse forming the line of dislocation, or the crevasses close to the side of the glacier, could have acted as a “hinge line” about which the vertical movement took place. Whatever the exact mechanism involved, it indicates that forces strong enough to overcome the contact between the glacier and its bed, to cause fracture of the ice, and to lift the ice front, were generated.

The final problem is the route by which the water escaped from Brimkjelen. There was no evidence that water escaped directly from the surface of the glacier, and even if it did, this would not have led to complete drainage of the lake. After the lifting of part of the glacier, it would perhaps have been possible for the water to have escaped subglacially from this section of the ice cliff. There was no direct evidence for this, however, and the mass of icebergs along the front of the ice cliff prevented inspection of the base of the ice. Assuming that this was the means by which the water escaped, there is still the problem of explaining how the water was able to penetrate the portion of the glacier that had not been raised up.

An oblique aerial photograph of Brimkjelen (Reference LiestølLiestøl, 1956, p. 135) shows that in 1954 the entrance of a tunnel was visible at the base of the ice cliff. This tunnel occurred at the lowest part of the valley floor, and it is possible that in 1962 the lake drained once again by way of this former route. In this area, towards the southern side of the valley, collapse of the ice was much more extensive in 1962 than along the remainder of the ice cliff. Large sections of the ice had subsided, rather than individual pieces breaking off the ice cliff. The collapse of the ice could have resulted from a lifting of this part of the ice barrier to initiate drainage, or alternatively, could have resulted from the release of water pressure against the ice cliff, after drainage had occurred.

Discussion

From the historical records available, it is evident that drainage of the lake followed the pattern suggested by Reference ThorarinssonThorarinsson (1939, p. 223). He considers that an ice-dammed lake experiences three stages during the general wastage and retreat of a glacier. Initially the lake is permanent; this is followed by a period of outbursts from the lake, which gradually diminish in intensity as the damming effect of the ice barrier becomes weaker, and finally the lake ceases to refill and a permanent outlet is maintained. It seems likely that in 1962 drainage from the lake had not completely attained the third stage suggested by Thorarinsson.

Reference ThorarinssonThorarinsson (1939) has suggested that drainage from an ice-dammed lake is initiated by lifting of the ice barrier, once the critical level is reached. This critical level is attained when the water is deep enough for the ice barrier to float and overcome the contact between the glacier and its bed. As an example, Reference LindsayLindsay (1966, p. 443) observed that 94 per cent of the ice cliff of an ice-dammed lake on the Casement Glacier, Alaska, was covered by water, before the ice barrier was lifted to allow the water to escape. From observations of Brimkjelen, it appears that in this case the critical level for floatation of the glacier was exceeded along part of the ice cliff, with water overflowing on to the surface of the glacier. All parts of the ice cliff may not necessarily experience the forces of floatation at the same time, because of the variations in height of the surface of the glacier in this area. Thus, the lower parts of the glacier, close to the valley sides, could undergo strong forces of uplift before the water could reach the critical level in the higher, central parts of the ice cliff.

Reference GlenGlen (1954, p. 318) has criticized the suggestion that an ice-dammed lake will drain completely after the ice barrier has been lifted. Once the level of the water in the lake falls below nine-tenths of the height of the ice barrier, the glacier will no longer be floating and outflow is likely to be prevented. From experiments on the mechanical properties of ice he has suggested that drainage may start when the water in the ice-dammed lake opens a tunnel as a result of the pressure of the water exceeding the pressure of the ice.

Reference LiestølLiestøl (1956, p. 123–25) has suggested that movement of a glacier over an irregular surface will open small cavities under the ice sufficient to allow water to penetrate and start the drainage from the lake. Once the water begins to flow, the tunnel under the ice will be widened by melting as a result of a heat surplus if the temperature of the water is above zero degrees Celsius. The oblique aerial photograph of Brimkjelen in 1954 (Reference LiestølLiestøl, 1956, p. 135) indicates that drainage from the lake has been through a tunnel overlain by almost 100 m of ice.

From the observations at Tunsbergdalsbreen, it is evident that both floatation of the ice (Reference ThorarinssonThorarinsson, 1939) and the formation of a subglacial tunnel (Reference GlenGlen, 1954; Reference LiestølLiestøl, 1956) have occurred, and it is suggested that drainage from the ice-dammed lake may be produced by a combination of these two processes. When the critical level was reached in the central parts of the ice cliff, uplift of the ice barrier would allow subglacial penetration of the water. The pressures then exerted by the water beneath the ice could have initiated drainage through the former subglacial stream course in the bottom of the valley.

Acknowledgements

The author would like to thank the members of the Brathay Exploration Group who have participated in this work; in particular, A. B. Ware, Director of the Brathay Field Studies Centre, and W. G. Jenkins and R. J. Lorimer, leaders of the 1962 Tunsbergdalsbre Expedition.

References

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Figure 0

Fig. 1. The location of Brimkjelen. The positions of the supraglacial extension of the lake and the irregular crevasse have been superimposed on the map produced by Kick (1966).

Figure 1

Fig. 2. Brimkjelen from the northern side of the valley. The height of the lake which occupied the valley is indicated by the upper limit of deposition of icebergs. Icebergs deposited on the surface of the glacier by the supraglacial extension of the lake can be seen at the bottom of the photograph. Part of the irregular crevasse runs down the centre of the medial moraine at the left side of the photograph.

Figure 2

Fig. 3. “Glacier tables” formed by small icebergs of white ice deposited on the glacier suface by the lake.

Figure 3

Fig. 4. Part of the irregular crevasse extending to the base of the low ice fall in the middle distance. This crevasse runs at right angles to the normal direction of crevassing in this area. Note the debris of the medial moraine on the surface of the glacier.