discharge of ice down the steep outlet glaciers. The broad and less active lobes on the northern margin of Mýrdalsjökull have not advanced yet. EROSION, DEPOSITION AND LANDSCAPES Landscapes in Iceland are to a great extent shaped by glacier erosion during the Pleistocene. This is evident from the Fjord, cirque and Alpine landscapes in the Tertiary basalt regions. The “Palagonite Formation” was built up by subglacial volcanic activity and later subject to glacier erosion. The lowlands in Iceland are the result of glacier erosion as well as marine abrasion. Large areas in the country are covered by glacial and fluvioglacial deposits. The erosion of the present glaciers in Iceland is still very intense although the glaciers have suffered deficit for several decades and the velocity slowed down considerably. Due to the high total budget the southern glacier outlets from Vatnajökull and Mýrdalsjökull are able to flow actively right down to the snouts. Typical valley glacier erosion is found in the basalt regions in southeastern Vatnajökull. The glacier outlets are deeply cut into the moun- tain range. The less active northern lobes terminate at higher levels. They have not been able to modify the bedrock by any deep erosion. The rate of glacier erosion has been estimated for various glacier basins by measurements of the sediment transport in glacier meltwater streams. Table I gives a sum- mary of the results for the main ice caps. TABLE I. Denudation of land estimated by sediment load transport (Tómasson 1976) Region Vatnajökull Mýrdalsjökull Hofsjökull Langjökull Other glaciers Unglaciated areas Rates of denudation mm/year 3.2 4.5 0.9 0.4 0.3 0.1 Glacier surges produce extremely high sediment loads. During the surge of Brúarjökull in 1963—64, Jökulsá á Brú carried on the average 6470 mg/1 in suspension. The total transport of sediments during the year was 25 - 106 tons which corresponds to a denudation rate of 13.7 mm/year. Two years later, in 1966, the sediment load had fallen to 1580 mg/1 in suspension and the total annual sediment trans- port was 6.6 ■ 106 tons. The high erosional activity of the glacier outlets which run south from Vatnajökull is evident in the very large sandur deltas which they have built out in front of their snouts in Postglacial time (Fig. 1 and Fig. 3). The wide glacier margins terminate on a broad lowiand area and the heavily laden melt- water streams spread widely into braided courses which change continuously and pendulate slowly across the outwash plain from one side to another. The lack of vegetation testifies to the migration of the channels. Jökulhlaups (glacier bursts) caused by rapid drainage of ice dammed lakes or by sub- glacial eruptions play an important role in building up some of the sandur deltas. About 60% of glaciers in Iceland are situated inside the active volcanic zone. Skeidarársandur (1000 km2) is the largest out- wash plain in Iceland (Fig. 3). It reaches 25 km inland from the sea and the average slope is 5 m/km. Skeidarársandur is the playground of jök- ulhlaups from the subglacial lake Grímsvötn which is situated in a geothermal area in the central region of Vatnajökull. During the last three to four decades jökulhlaups from Grímsvötn have occur- red approximately twice each decade and the total water volume in each jökulhlaup has been roughly 3—3.5 km3 and the maximum discharge of the order of 10000 m3/s. Each jökulhlaup has carried about 30 ■ 106 tons of sediments down to Skeidarár- sandur. Earlier in this century one jökulhlaup with a water volume estimated to be the double of that of recent jökulhlaups occurred each decade with a maximum discharge of up to 40000 m3/s. Some of these jökulhlaups were accompanied by volcanic eruptions in Grímsvötn. During the eruption in Grímsvötn in 1934 the total sediment transport down to Skeidarársandur was of the order of 150 ■ 106 tons. Further, the western part of Skeidarár- sandur has been flooded by the lateral ice dammed lake Grænalón. The maximum discharge of jökul- hlaups from Grænalón has been of the order of 5000 m3/s. During the recent glacier recession jök- ulhlaups have become more frequent but smaller in volume due to the thinning of the damming ice barriers. Also, the number of dumping glacier lakes has been greatly reduced. Mýrdalssandur, Sólheimasandur and Skóga- sandur have been built to a large extent by jökul- hlaups caused by volcanic eruptions of the ice cov- JÖKULL 29. ÁR 79

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