the area was eroded by an ice cap which flowed towards the south or east, perpendicular to the coast. In this area one finds two of the best known lateral glacier lakes in Iceland, Græna- lón and Vatnsdalslón. A few glacier-margin lakes are found in the active volcanic zone. Most of these lakes are proglacial (or frontal) and located in depressions between the NE-SW running hyaloclastic ridges. No transverse val- leys have been eroded in this relatively young landscape. Therefore, lateral lakes are rare in the active volcanic zone. A number of proglacial lakes have turned up in this century in front of the rapidly retreating glaciers. Most of them have disappeared again and only the main pro- glacial lakes are shown in Fig. 2. Most lateral lakes are at present sources of jökulhlaups, however small. Some of the pro- glacial lakes are potential sources of jökulhlaups. Hamarslón and Hvítalón can become damrned when the neighbouring glaciers surge (Frey- steinsson, 1972). Further, the lakes south of Langjökull were dammed by the glacier up to the late 1920:s. To the south the lakes are bound by the lava sheet Lambahraun and when the glacier advances the natural outlets of the north- western edge of the lake can be dammed up (see Wright (1955), Kjartansson (1938), Thorar- insson (1939, 1966), Green (1952) and Sigbjarn- arson (1967)). Glacier advance would result in the forma- tion af small lakes in ravines at the glacier margin. Frequent but small jökulhlaups may occur from these lakes. The advance of the out- lets of Mýrdalsjökull, like Höfdabrekkujökull and Sólheimajökull in the last few years, has already caused small jökulhlaups (Einarsson 1973, see also Björnsson and Einarsson, this issue p. 58). One of the lakes which would form again is Ker which up to the 1950:s was dammed between the mountain Kerfjall and Múlajökull, SE-Hofsjökull (Gestsson, 1956). But thickening of the ice barrier of already existing lateral lakes woulcl decrease the frequency of jökulhlaups and increase the water volume. JÖKULHLAUPS FROM GRÆNALÓN AND VATNSDALSLÓN - TRIGGERING Data are available on the topography and the jökulhlaup history for the two main ice- dammed marginal lakes at Vatnajökull. Grænalón is the largest marginal lake in Ice- land (64°11'N, 17°24'W), Áskelsson (1936), Kjart- ansson (1938), Thorarinsson (1939). The lake is located in an ice-free tributary valley which is dammed up by the western margin of Skeidar- árjökull, which is an outlet at the southern edge of Vatnajökull. During the last century the lake drained over a col at 635 m to the river Núpsvötn. But in 1898 the lake was emptied in a jökullilaup which ran subglacially the whole waterway down to the rivers Súla and Blautakvísl at Skeidarársandur. From 1901 up to 1935 the lake drained again over the col. In 1935 a jökulhlaup occurred again. The total volume of the jökulhlaup was about 1500- 106 m3. The lake area before the jökulhlaup was 19 km2. The maximum depth of the lake was 180 m. Fig. 3. shows a cross-section of the lake and the glacier at the start of the jökullilaup in 1935. The next jökulhlaups occurred in 1939, 1943, 1946, 1949 and 1951. Since 1951 the jökulhlaups have become more frequent and less volumin- ous, occurring once or even twice a year. Further, the jökulhlaups do not run subglacial- ly beneath the whole glacier but lift a shallow ice barrier at the glacier margin and run along- side tlie glacier down to Skeidarársandur. Typi- cal values for the latest jökulhlaups are: total volume of 200 • 108 m3 and maximum discharge of 2000 m3/sec The maximum area of the lake is about 13 km2 and the lake level drops only about 20 m in each jökulhlaup (see Rist 1970, 1973). Vatnsdalslón is dammed up in the tributary valley Vatnsdalur by the eastern margin of Heinabergsjökull (Thorarinsson 1939). The first jökulhlaup in recent times occurred in 1898. Up to that date the lake drained over a col at 464 m into the valley Heinabergsdalur. The total volume of the jökulhlaup was 120- 106 m3 and the estimated maximum discharge 3000 m3/sec. Fig. 4 shows the cross-section of the glacier and the lake at the start of the first jökulhlaups at the end of the last century; lake area 1.9 km2. In the present century the jökulhlaups have be- come more and more frequent and less volum- inous, occurring even twice a year (Rist 1973). However, the drainage is still subglacial be- neath the whole length of the glacier. Consider the triggering of the jökulhlaups. A floating model predicts a jökulhlaup when the JÖKULL 26. ÁR 43

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