S U M M A R Y TRITIUM IN GROUND WATEli AND GLACIERS IN ICELAND Páll Theodórsson Science Institute, University of Icelancl. Since 1962 an extensive grouncl water in- vestigation using the hydrogen isotopes has been carried on at the Science Institute of the University of Iceland. The main emphasis has been on the geothermal ground water, study- ing the geographical variation of the average deuterium concentration in precipitation, sur- face water and in ground water. Similar studies have been made of the time variations of the tritium concentration. As a part of this work tlie deuterium and tritium concentration in two of the largest glaciers have been studied. The main results of the tritium measurements in two boreholes in the glaciers Langjökull and Vatnajökull are described in this article. The holes were made with á thermal drill, which is shown on Figs. 2 and 3. At the lower end of a 1.2 m long tube 70 mm in diameter, there is an annular electric heater, which melts the ice, leaving a 45 mm diam. ice core. The power in the heater was about 300 watts and the drilling speed 1—2 meter per hour. The first hole with the thermal drill was made on Langjökull in May 1968. The depth of the hole was 30 meters. The result of the tritium measurements on this core is shown on Fig. 5. This figure shows clearly that there is an extensive isotopic exchange between the rain and meltwater and the ice of the glacier. At this altitude the accumulation of snow be- gins probably in the beginning of October and ends in April. It is further assumed that the snow of March—April melts again. There- fore the mean tritium concentration of the wintermonths, October—February, is also shown on Fig. 5, and the scale of the abscissa is chosen to give the best fit to the tritium curve of the glacier. It has generally been accepted that there is only slight isotopic exchange be- tween the ice and percolating meltwater in a temperate glacier. Fig. 5 shows that this can- not be the case. The same is also amply de- monstrated by the deuterium measurements. The tritium variations in the glacier must be explained with the modifying influence of summer rain and meltwater. The mean tri- tium value of the precipitation of March— September (at Rjupnahaed) is therefore shown on Fig. 5. It is hoped that these results to- gether with proper mathematical analysis will give valuable information about the exchange process. In June 1968 another hole was drilled at Bardarbunga in Vatnajökull, the largest gla- cier in Iceland, at an altitucle of 1800 meters. The deptli of this hole was 40 meters, but then the drill got stuck and coulcl not be re- covered. The result of the tritium measurements of the icecore is shown on Fig. 6. The monthly mean value of the tritium concentration in precipitation at Rjupnahaed is also shown on Fig. 6, the scale of the abscissa being chosen so as to give best fit. The two curves are quite similar, indicating that the glacier is arctic or at least very nearly so. It should therefore be possible to obtain a continuous record of the tritium concentration in precipitation during the last decades by drilling deep enough into the glacier at Bard- arbunga. This would be of great value for tritium measurements, as it is important to know the tritium concentration in rain before the atmosphere became contaminated with tri- tium from hydrogen bombs. It is also anti- cipated that deuterium measurements of such an ice core could give interesting information. An attempt will therefore be made to drill a deeper hole into the glacier in the summer 1969. This work will be reported in greater detail after further measurements have been made. 358 JÖKULL 18. ÁR

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