and in the Jarlhettur Valley as can be clearly seen on photograplis from the years 1929 and 1934. Wright (1935) measured the discharge through the Leynifoss Col under high water conditions in the year 1934 and it was then only about 6 m3/sec. “Jökulhlaups” from Hagavatn As mentioned five “jökulhlaups” have been reported from the Hagavatn area. The last two were investigated, and it is therefore known what changes in drainage were caused by these events, except that the drainage conditions be- fore the “jökulhlaup” of 1929 are unknown. The “jökulhlaup” of 1929 escaped directly through the Leynifoss Col and the lake level was lowered 6.3 m (Ólafsson 1929, Wright 1935), but in tlie year 1939 Hagafellsjökull Eystri had receded so far that the water could be released through the present outlet, the Nýifoss Col, and the lake level was lowered 9.5 m, from level 3 to level 4 on Fig. 5 (Thorarinsson 1939). The released volume of water in these two latest “jökulhlaups” was probably greater than in the earlier ones, so that they cannot be explained by a recurrence of the same events. As men- tioned earlier, the height of the shore line be- fore 1929 corresponds approximately to the height of the channel along the north slopes of Brekknajökull. The “jökulhlaup” of 1929 probably occurred because the drainage moved from this channel and the lake level was lower- ed from 2 to 3 on Fig. 5. As mentioned above, there is a good correlation between the highest one of the shore lines and the delta terrace at the NW corner of Brekknafjöll. For some time the terrace has determined the elevation of the lake level. The glacier burst in the year 1902 probably occurred because the glacier snout had retreated a little from the delta terrace and tlie water could then drain on the north side of it. In this way the lake level sub- sicled frorn 1 to 2 on Fig. 5 or about 4—5 m, and about 45 million m3 of water were releas- ed, wliich is in fairly good correspondence with what is told about its magnitude in comparison with the “jökulhlaup” of 1929 (Ólafsson 1929), when 65 million cubic meters of water were released from the Hagavatn during 24 hours (Wright 1935). A comparable volume of water was released in the “jökulhlaup” of 1939, but this time distributed over three days. The latter therefore caused much less damage than the former (Thorarinsson 1939). No attempt will be made here to explain the causes of the “jökulhlaups” in the years 1708 and 1884, but they most likely represent some recession of the Flagafellsjökull Eystri, allowing the water to escape through some lower subglacial tunnels. Thorarinsson (1939) suggests that the “jökul- hlaup” in 1702 escaped through the Nýifoss Col and in 1884 through the Leynifoss Col, but they might also have originated from ice-damm- ed marginal lakes in the Jarlhettur Valley. The changing drainage The glacial retreat has brought about changes in drainage conclitions at the southern margin of Langjökull. Here the bedrock is mostly post- glacial lavas and other very permeable rocks, where no surface drainage is found. It is al- most certain that the ground water drains to the rivers Sog and Brúará, while the surface run-off from the glacier flows through Haga- vatn and from there into the Tungufljót river. As formerly discussed the lake level of Haga- vatn was up to 22 m higher than the present one and three other marginal lakes were form- ed along the glacier margin west of Hagavatn (Fig. 7) during the time of the greater extent of the glacier. The glacial retreat caused succes- sive lowerings of the Hagavatn lake level and the emptying of the three western lakes, which took place sometimes between 1950 and 1960, but in that year they had all disappeared. It can be asserted that great leakage through the bottom of these lakes was yielded to the ground water storage, especially during their formation before the glacial silt and clay had tightened their bed (Tómasson 1964). During this time a great part of the melt water from the south- ern part of Langjökull has been drained as ground water. At the present time the surface drainage from Langjökull flows on compara- tively impermeable moraine. The decrease in the discharge of the river Sog can at least part- ly be explained by this process (Sigbjarnarson 1966). It can be stated that during the last decades Tungufljót has been capturing water from the Sog and the Brúará. JÖKULL 17. ÁR 269

Blaðsíða 1
Blaðsíða 2
Blaðsíða 3
Blaðsíða 4
Blaðsíða 5
Blaðsíða 6
Blaðsíða 7
Blaðsíða 8
Blaðsíða 9
Blaðsíða 10
Blaðsíða 11
Blaðsíða 12
Blaðsíða 13
Blaðsíða 14
Blaðsíða 15
Blaðsíða 16
Blaðsíða 17
Blaðsíða 18
Blaðsíða 19
Blaðsíða 20
Blaðsíða 21
Blaðsíða 22
Blaðsíða 23
Blaðsíða 24
Blaðsíða 25
Blaðsíða 26
Blaðsíða 27
Blaðsíða 28
Blaðsíða 29
Blaðsíða 30
Blaðsíða 31
Blaðsíða 32
Blaðsíða 33
Blaðsíða 34
Blaðsíða 35
Blaðsíða 36
Blaðsíða 37
Blaðsíða 38
Blaðsíða 39
Blaðsíða 40
Blaðsíða 41
Blaðsíða 42
Blaðsíða 43
Blaðsíða 44
Blaðsíða 45
Blaðsíða 46
Blaðsíða 47
Blaðsíða 48
Blaðsíða 49
Blaðsíða 50
Blaðsíða 51
Blaðsíða 52
Blaðsíða 53
Blaðsíða 54
Blaðsíða 55
Blaðsíða 56
Blaðsíða 57
Blaðsíða 58
Blaðsíða 59
Blaðsíða 60
Blaðsíða 61
Blaðsíða 62
Blaðsíða 63
Blaðsíða 64
Blaðsíða 65
Blaðsíða 66
Blaðsíða 67
Blaðsíða 68
Blaðsíða 69
Blaðsíða 70
Blaðsíða 71
Blaðsíða 72
Blaðsíða 73
Blaðsíða 74
Blaðsíða 75
Blaðsíða 76
Blaðsíða 77
Blaðsíða 78
Blaðsíða 79
Blaðsíða 80
Blaðsíða 81
Blaðsíða 82
Blaðsíða 83
Blaðsíða 84
Blaðsíða 85
Blaðsíða 86
Blaðsíða 87
Blaðsíða 88
Blaðsíða 89
Blaðsíða 90
Blaðsíða 91
Blaðsíða 92
Blaðsíða 93
Blaðsíða 94
Blaðsíða 95
Blaðsíða 96
Blaðsíða 97
Blaðsíða 98
Blaðsíða 99
Blaðsíða 100
Blaðsíða 101
Blaðsíða 102
Blaðsíða 103
Blaðsíða 104
Blaðsíða 105
Blaðsíða 106