bunga encirded by the high rim exposed up to 1850 m on the west side. The flattening of the ice sheet on Bárdarbunga and the steepness of the outer slopes suggests a buried caldera. Likewise, the high feature of the area to the east of Hamarinn is likely a central volcano complex. There is even a small central depres- sion in it which suggests a central vent. This “central vent” may also be related to the sub- glacial geothermal or volcanic activity which has caused the three prominent subsidence fea- tures to the east. The depressions seen on tlie ERTS-1 image near the northern rim of the Grímsvötn caldera form or deepen after eacli jökulhlaup from Grímsvötn (cf. the American Army Map Service map of Grímsvötn, scale 1:50,000, Sheet 5920, II, 1950, Series C762*). They are most certainly the result of permanent subglacial geothermal activity and subsidence of the overlying ice, following the withdrawal of meltwater. In one such depression a large solfatara was observed after the jökulhlaup from Grímsvötn in 1954 (Thorarinsson, 1955). The series of shallow de- pressions forming a chain E to SSE of Gríms- fjall probably show the subglacial course of the floodwater from the March 1972 jökulhlaup from Grímsvötn. The image also suggests that the Grímsvötn depression consists of two cald- eras. The area around the nunataks, Geirvörtur and Pálsfjall, and the areas of Háabunga, Thórdarhyrna, and Hágöngur, are most inter- esting from a structural viewpoint. Thorarins- son’s map (1950) showed a possible structural alignment of Geirvörtur—Grímsvötn, and on its continuation to the northeast he suggested a probable eruption center in Dyngjujökull. On the map this center lies 10 km to the west of Kverkfjöll. On the ERTS-1 image, however, a volcano-tectonic lineament whicli strikes N. 45° *) The aerial photography of the Grímsvötn area, which was used to prepare the 1:50,000- scale map of Grímsvötn was acquired by the USAAF in Aug. 1945 and Aug.—Oct. 1946, during the month before and year after a jökul- hlaup. The unusual “composite” map is the best map available of the morphology of the caldera after a jökulhlaup, and thus is similar to the situation portrayed on the ERTS-1 image. 1 2 JÖKULL 23. ÁR E. can be traced from Hágöngur in the south- west across Grímsvötn to Kverkfjöll in the north- east where it cuts in half what appears to be a caldera southwest of Kverkfjöll, and finally merges with the trend of the solfatara valley in Kverkfjöll. This structural lineament extends at least 80 km from the southern to the north- ern edge of Vatnajökull — extending from Sídu- jökull to Kverkfjöll. It continues to the north- east and to the southwest of Vatnajökull as the line of demarcation between areas of active volcanism to the west and extinct volcanism to the east. The same relationship probably holds true for tliat part of it which is covered by the ice sheet. In the Kverkfjöll area two elliptical features are well exhibited. Both are about the same size, 8 km x 5 km, but whose long axes are oriented differently to each other. The long axis of the elliptical structure southwest o£ Kverkfjöll is oriented about N. 30° W. An apparent linear depression cuts N. 45° E. across its northern side and merges with the 80 krn long volcano-tectonic lineament previously dis- cussed. Southwest of the structure this linear depression is less distinct (with some parallel linear features) but continues to the southwest for at least 10 km. Just as the alignment of the hot springs and solfataras of Hveradalur was shown, through analysis of aerial thermography (Friedman a?id others, 1972) to extend to the northeast under Kverkfjöll, the ERTS-1 imag- ery shows that the Hveradalur thermal activity is also manifested to the southwest for a con- sidererable distance. Therefore, it is suggested that this northwest- trending elliptical feature is the subdued sur- face expression of a subglacial caldera. It is also likely that this subglacial caldera is the “possible eruption center” in Dyngjujökull which was previously discussed by Thorarins- son (1950). Thorarinsson suspected such a sub- glacial volcanic center because of the occurrence of historical jökulhlaups on Jökulsá á Fjöllum. Fig. 3. Enlargement of eastern part of Vatna jökull to 1:500,000 scale. [NASA ERTS-1 image (MSS), 1192-12084.] Mynd 3. Stœkkun af austanverðum Vatnajökli (M 1:300 000).

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