Fig. 7. The course of the jökulhlaup after it subsided in early April 1972. The course is cover- ed with black sand and a silt layer. The area on Fig. 6 is also shown on this picture. Mynd 7. Farvegur Grims- vatnahlaupsins, eftir að það hafði sjatnað snemma í april 1972. Farvegurinn er þakinn svörtum sandi og mó. Svceðið á Mynd 6 er einnig á þessari. normal grain size differs very much from one locality to another. As a general rule it becomes finer grained further downstream. This layer is usually very coarse at top and is considered to reach down to the next very coarse layer. This stratification, which is very coarse in- deed, is due to the mode of transportation of the coarse material. Branches are cut down un- til protected by a stone layer. Then gravel bars accumulate on top of it and again some erosion and formation of a protective stone layer takes place again. This may be repeated many times during the jökulhlaup. The fresh appearance of this layer indicates that layer 2 is usually new, redeposited in the jökulhlaup. The thick- ness of this layer is usually about 1 m in the upper part ancl thins out downstream. The volume of this layer is estimated at 45 Gl. The distance it has been brought down- stream is not known, but based on bedload measurement and changes in the flood channel it is estimated as 3 km. Another effect is the widening of the channel by bank erosion. Along Skeidará the right bank was eroded in the upper reach, usually a few tens of meters, forming a bank a couple of meters high. At Gígja much higher banks were eroded and much more material brought into the channel that way. Both banks were eroded there, but the right bank to a much greater extent. The net effect of these factors was measured at Skeidará by observing the river level both before and after the jökulhlaup in relation to piles driven down by the Public Roads Ad- ministration in a line along Skeidará from Skaftafellsbrekkur and approximately 10 km downstream. In the uppermost part there was insignificant difference, about 15 cm net accu- mulation midway on the line and an erosion of a few tens of cm at the lower end of the line. Along Skaftafellsbrekkur there seems to be some net accumulation and from there to the glacier a net erosion. In all these calcula- tions the unstable layer 1 is left out. At Gígja there was obviously considerable net accumula- tion except in the uppermost part. This accu- mulation was mainly due to bank erosion. Sampling of suspended sediments at the main outlets into the sea at the highest peak in sedi- ment discharge indicates that most of the sedi- ment load is cleposited on the Sandur plain. This is mainly sedimented as layer 1 as already discussed. About 10- 106 m3 have been aclded to the sancl which makes a 4 cm thick layer over the entire flood channel. The remaining about 5 • 10° m3 of sediment load is deposited close to the shore. Suspend- ecl in the sea on the 27th of March were 1.1 • 10° tons. 70% of the total clay is found there, 13% of total fine silt and less than 1% of total coarse silt. This indicates very rapid sedimenta- 34 JÖKULL 24. ÁR

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