Glaciological application of InSAR topography data of W-Vatnajökull Some critical points exist, in the static potential field, where we obtained ambiguous results for the water divides. For example, the model can not pre- dict with any certainty whether water from the area north of the star in Figure 2 should drain to the rivers Hverfisfljót or Djúpá. It is also uncertain whether water from the areas north of regions marked by di- monds drains into Skaftá or elsewhere. The area north of the southernmost diamond could belong to the Hverfisfljót river basin and the northern area the Sylgja/Bryðja river basin. The two areas north of the diamonds in Figure 2 will be referred to later as the uncertainty areas for the Skaftá and Hverfisfljót river basins. The water divides around Sylgjujökull are also uncertain since the outermost part of this outlet glacier has not been mapped in detail by radio echo sounding. For example, a ridge clearly observed in the surface DEM of Sylgjujökull is missing in the basement DEM. Due to this ridge, the river basin of Skaftá might be substantially larger at the expense of Sylgja/Bryðja and even Kaldakvísl river basins (Fig- ure 2). Estimates of summer balance within the water divides of Djúpá and Hverfisfljót (Björnsson et al., 1998, 2002) were compared with river discharge mea- surements during June to September (Figure 3), pro- vided by the National Energy Authority. The glacier meltwater contribution during the summer was cal- culated by subtracting the direct runoff, attributed to precipitation, from the measured river discharge, as- suming that the volume of ground water draining each river basin equals the measured runoff from that basin. The direct runoff for each river was crudely estimated by scaling the precipitation measured at Kirkjubæj- arklaustur (www.vedur.is/vedurfar/yfirlit/medaltalstoflur/ Stod − 772 − Kirkjubajarklaustur. ManMedal.txt, 2003) with the area of the river basin below 1100 m. The pre- cipitation above 1100 m is hard to estimate based on the Kirkjubæjarklaustur data, as it lies significantly further away from the station. It is also uncertain to which river the area above 1100 m is connected (Fig- ure 2). Excluding this region causes an underestimate in the direct runoff for the river draining it, leading to an overestimate in the glacier contribution for this river. Discharge values and summer balance measure- ments agree fairly well, especially since 1999, assum- ing that the area west of Grímsvötn is connected to Hverfisfljót. The difference in 1996 to 1998 could be due to higher negative balance for Síðujökull as a re- sult of its surge in 1994 (Björnsson et al., 2003). The summer balance is not measured specifically for Síðu- jökull but estimated from direct measurements from Tungnaárjökull and Breiðamerkurjökull and in some years from Skeiðarárjökull as well. The average ratio between the glacier runoff, dur- ing the summer, in Hverfisfljót and in Djúpá and sum- mer balance is around 3 assuming the area west of Grímsvötn drains to Hverfisfljót and 0.9 if it drains to Djúpá, while the corresponding average ratio esti- mated from the measured river discharge and the pre- cipitation is 2.2 ± 0.7 assuming an error of up to 50% in the precipitation contribution. The results indicate that most or all of the water from the area directly west of Grímsvötn drains into Hverfisfljót. The possi- bility of a minor amount draining into Djúpá should, however, not be rejected. The derived water divides for both branches of the river Skaftá are also of interest. According to the static potential model, the river basin of the eastern branch extends into the Skaftá cauldrons (Figure 2). How- ever, discharge from the Skaftá cauldrons during re- cent jökulhlaups all drained into the western branch (Bjarni Kristinsson, pers. comm., 2003). This dis- crepancy could be caused by several effects; The wa- ter pressure during jökulhlaup may be totally different from normal conditions drasticly changing long-term water divides and flow paths. One might argue that water in jökulhlaups tends to drain in pre-existing tun- nels. This might be true in many cases but the shape of the hydrographs for jökulhlaups in Skaftá suggests that their water does not pass through a single tunnel but instead spreads out as distributed flow (Björnsson, 1992). A simple model may apply to the more regu- lar jökulhlaups in Skeiðará only whereas distributed flow is acquired to explain larger events such as the >3 km3 jökulhlaup in 1996 (Björnsson, 2002) which emerged into all rivers draining Skeiðarárjökull, al- though initially bursting into Skeiðará. This model may also oversimplify the water divides between in- JÖKULL No. 54 21

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