during the period before the 1972 jökulhlaup. The difference of 0.5 km3 is roughly equal to the water that accumulates in Grímsvötn dur- ing an 11 months period. Many jökulhlaups have been accompanied by volcanic eruptions in the mountains surround- ing Grímsvötn, e. g. in 1922 and 1934. Thorar- insson (1953) observed that these eruptions do not. c.ause the jökulhlaups, and he suggested that the eruptions might be triggered by the pressure drop at the volcano as the water drains out of Grímsvötn. Volcanic eruptions inside the water basin north of Grímsvötn could trigger jökulhlaups from Grímsvötn by adding extra meltwater to the lake, and this is what might have caused the jökulhlaup in 1938. Volcanic eruptions inside Grímsvötn, on the other hand, can hardly trigger unexpected jökulhlaups as they could only melt the ice cover on the lake and could not raise the water level. (This as- sumes, of course, that the volume of the vol- canic materials introduced into Grímsvötn is negligible compared to the volume of the lake. The average volcanic eruption in Iceland pro- duces about 0.2 km3 of volcanic materials com- pared with the lake’s volume of, say, 3 km3). An eruption at the subglacial ridge east of the lake, causing melting of ice at the threshold, could cause a jökulhlaup by breaking the seal. It might also change the release mechanism by increasing the height of the subglacial ridge and by reducing the glacier thickness. If 13 vol- ume units of ice were melted for one volume unit of volcanic material introduced, the glacier surface would drop more than the subglacial ridge would rise; although the water level in Grímsvötn would have to rise higher than at present to give a certain value of the hydraulic head relative to the height of the new ridge, the glacier which would have to be lifted would be much thinner than the present one. It may take some decades for the glacier at the seal to attain a height appropriate to the climate conditions. After that a higher water level in Grímsvötn would be required to lift the glacier and the jökulhlaups would be greater in vol- ume. The mass balance model predicts water vol- umes for the jökulhlaups which are in a reason- able agreement with the estimated runoff in the rivers on Skeidarársandur. This model should, however, be subject to further tests. Detailed data on the mass balance ancl the'ice velocity should be collected in the water basin. The bottom topography of the lake should be mapped. This map, together with data on the rate of rise of the water level (Fig. 3) in the lake, would give the best estimate of the filling rate of the lake. The present study does not confirm Malm- berg’s (1974) estimates of the jökulhlaup in 1972. His estimate of water volume was only i/3 to i/, of Rist’s (1973) estimate. In the present theory no attempt is made to link the reported observations (Thorarinsson, 1974; Stefánsson, 1973) of a rise of the lower part of Skeidarárjökull to the explanation of the jökulhlaup mechanism. On the whole, they seem to be somewhat contradictionary and do not appear to be an essential part of the re- lease mechanism. They should, however, be thoroughly examined. Plastic deformation as a trigger mechanism. Glen (1954) advanced the hypothesis that water might escape from Grímsvötn by causing plastic deformation of the ice. Consider a gen- eral model of water in a vertical hole in the glacier. The difference between the water pres- sure and the ice overburden pressure far from the hole is (^) Pw§ Pi fí li in which lw is the depth of the water in the hole and 1; is the length of the hole, pw and p, are the density of water and ice, respectively, and g is the acceleration of gravity. Glen’s (1954) model of a water-filled hole is the special case for which lw = lj. For a lw of 200 m he obtainecl a Ap of 2 bars, which induces a shear stress of 1 bar on planes at 45° to the hori- zontal. Deformation of the ice at the bottom of the hole would then allow water to penetrate the ice. However, such a model does not de- scribe the situation in Grímsvötn. If a water-filled hole were to reach the glacier bottom one would expect lifting of the glacier. Also, the hole may be only partly filled with water. A water depth for which the water pres- sure at the bed matches the ice overburden pressure could cause lifting of the glacier. Since lifting of the glacier can occur at lower water 22 JÖKULL 24. ÁR

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