Eyjólfur Magnússon et al. served displacement has a significant cross track com- ponent relative to the modelled flow direction, partic- ularly in 1946–1985 and again in 2011–2014. This may indicate that these features do not only move with the glacier surface but also migrate in the sur- face. The direction of the migration may be associ- ated with the alignment of the crevasses opening in the surges, traversing these depressions approximately in the cross track direction of the flow, and existing un- derneath the snow cover for years after the surges. Wind scouring and snow drift may also cause dif- ference in snow accumulation between the north and south end of the depressions enhancing migration of these features in a northward direction. CONCLUSIONS The dense RES-survey of Drangajökull ice cap has produced the most detailed bedrock DEM of an Ice- landic ice cap, available at present. The bedrock to- pography of Drangajökull is similar to its vicinity (i.e. the Vestfirðir peninsula). The ice cap volume is 15.4±0.4 km3 with an average thickness 107±3 m, relative to the glacier surface in July 2011. The corre- sponding values relative to the surface of March 2014 are 16.1±0.4 km3 for volume and 112±3 m for av- erage thickness. The largest proportion of the ice is stored in the ice catchment of Kaldalónsjökull or 4.6±0.1 km3 (∼30% of the total volume) and it also includes the thickest glacier measured, 284±14 m (relative to July 2011). In 2011 about 71% of the ice cap volume was stored in the ice catchments on the west side of the Drangajökull (Leirufjarðarjökull, Kaldalónsjökull and SW-Drangajökull). The east part of Drangajökull, with both less vol- ume and significantly thinner ice, has also been losing volume at ∼3 times faster rate on average than the west part of the ice cap. The glaciers on the west side, will therefore exist for much longer than the glaciers on the east side if the observed pattern of retreat con- tinues. Thus glacial melt water in the rivers draining towards east will disappear long before it disappears in rivers draining west, if similar retreat continues. By integrating the glacier thickness, obtained from the difference between the bed DEM and surface DEMs at various times, a record of the ice cap volume has been obtained. This record shows that Dranga- jökull’s volume was reduced from ∼18 km3 in the autumn of 1946 to ∼16 km3 in the autumn 1975, fol- lowed by ∼0.5 km3 volume gain until the fall of 1994. In the autumn of 2014 the volume of Drangajökull corresponded to ∼15 km3, corresponding to ∼17% volume reduction since 1946. Around half of this re- duction occurred in the period 1994–2011. The sea- sonal fluctuation in the volume of Drangajökull cor- responds to around a third of the net volume change since 1946. The detailed RES-data reveals several interesting features of Drangajökull ice cap. These include: Significant horizontal shift between the surface crest and the topographic ridge in the glacier bed at the ice divides between the east and west part of the ice cap. This is particularly pronounced south of the summit, Jökulbunga, where the surface crest is typi- cally shifted 300–600 m in SW direction relative to the bedrock ridge. The direction of the shift fits well with the governing snow drift direction from NE. Due to this mismatch, it is likely that water divides be- tween the eastern and western drainage catchments of Drangajökull will propagate eastwards if thinning of the glacier continues, enlarging the drainage catch- ments of Mórilla and Selá at the expense of Reykjar- fjarðarós and Bjarnarfjarðará. Typical ice thickness of 40–60 m underneath de- bris patches of Langahraun near the margin of SW- Drangajökull. Prior to this work it was not known that Langahraun is debris covered glacier ice. A faint internal layer that can be traced from the surface at the upper edge of Langahraun down to the bed over a dis- tance of ∼300 m implies that Langahraun is partially accumulated debris, which has been scraped from the glacier bed and transported to the surface by a main glacier sliding over a smaller ice unit. Ridges and troughs beneath S-Drangajökull with dominant N-S strike, of which some can be traced across the ice cap. The same alignment in landforms is very common south and east of Drangajökull and is most likely joints and fractures in the bedrock. The new bed DEM opens opportunity for further studies of Drangajökull ice cap, e.g. numerical ice flow modelling. An example shown here is a study 22 JÖKULL No. 66, 2016

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