level z0. In a period of five or six years the water level rises about 100 m and a jökulhlaup results. An ice cauldron of 30 km2 is formed, the so called Grímsvötn-depression. Jökulhlaups due to subglacial volcanic eruptions The main ice caps in Iceland are all located within the active volcanic zones. Subglacial eruptions can cause sudden jökulhlaups. Consider the effect of a fissure eruption be- neath a sloping ice cap. Magmatic heat will cause considerable local melting at the bed of the glacier. One may expect the meltwater to flow away from the site of the eruption towards the edge of the glacier. The flow in the water- ways is limited by the production of meltwater. The rate of opening of the waterways by melt- ing may be balanced by the rate of closing by plastic deformation (cf. Nye in press). So far, the model agrees with Tryggvason (1960). A depression will be formed in the glacier sur- face above the eruption site. The ice over- burden pressure at the bed surrounding the depression will exceed the water pressure at the subglacial water reservoir. The waterways which run out from the reservoir may therefore be- come sealed by plastic closure. Meltwater would then be trapped beneath the depression. A water cupola will become located as a cap on top of the volcanic vent. Lava erupts directly into water. A rapid heat transfer takes place by boiling of water (at ice depths less than 2400 m as the critical pressure for water is 220 bar). Water and volcanic products are then accumu- lated in a closed system. In a rnodel of perfect heat transfer one volume unit of lava melts thirteen volume units of ice, which equals twelve volume units of water. The lava would take up the free space created by melting. In a more realistic model of imperfect heat transfer the volume of lava would exceed the free space. Therefore, the water cupola will rise beneath the depression and jökulhlaups may be expect- ed from the reservoir. After a jökulhlaup the subglacial waterways may become sealed again. A few jökulhlaups might occur during a long eruption rather than one catastrophic jökul- hlaup. — After an eruption water will ac- cumulate beneath a depression in the glacier surface. Ice and water would flow into the de- pression and cause a jökulhlaup. If the geo- thermal activity decays, ice will gradually fill the depression and the jökulhlaups cease in the end. (Observations do not indicate such a de- velopment at the ice cauldron north-west of Grímsvötn, Björnsson in preparation). Table-mountains and hyaloclastic ridges are considerecl to be formed by subglacial eruptions (Kjartansson 1943, 1964, 1966, Matheivs 1947, van Bemmelen and Rutten 1956, Jones 1969). Studies of the shape and structure of these mountains indicate a certain growth sequence. During the first phase lava appears to erupt directly into a water-filled vault. The structure of subglacial and submarine volcanoes were expected to be similar. The birth of the island Surtsey in 1963 provided a virtual example of the creation of a submarine volcano. The pre- sent paper explains how the water-filled vault may be formed during a subglacial eruption. Fig. 6 shows a model for the generally accepted growth sequence of a table-mountain. The sub- glacial volcano is built within a water cupola which would explain why the base length of the volcanoes is multiplum of its height (cf. Einars- son 1972, p. 111). The shape of the water cupola is determined by the shape of the glacier sur- face depression according to Equation (8). This explains why a subglacial volcano can be ex- pected to be more confined and more steepsid- ed than a submarine volcano. Further, sub- glacial volcanoes are built up inside ice-locked water whereas the submarine volcanoes are con- stantly dashed by oceanic waves. Grímsvötn and Katla are the most active sub- glacial volcanoes in Iceland. Both volcanoes are situated at geothermal areas. Jökulhlaups are frequent from both sites. A strong geothermal area has created a large water reservoir at Grímsvötn, say 3 km3 in volume. In a period of five or six years the water level rises about 100 m and a jökulhlaup occurs. Volcanic erup- tions within this reservoir cannot trigger un- expected jökulhlaups. The accumulation of vol- canic materials can only raise the water level by a few meters. An input of, say 0.3 km3 of volcanic materials would raise the 30 km2 water surface by 10 m. Melting of the floating ice cover does not raise the water level, and the inflow of the surrounding ice is a relatively slow process. However, a volcanic eruption within the water cupola 10 km north-west of Gríms- vötn might at any time trigger jökulhlaups. JÖKULL 25. ÁR 9

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