and the area around Höfn. Although this ERTS-1 image of Vatnajökull shows the largest area of the icecap of any image, other ERTS-1 images, acquired at different times, show other parts of Vatnajökull. Therefore, in the space of about 8 months, most of the Vatnajökull was imaged by the multispectral scanner sensors on the ERTS-1 satellite. METEOROLOGICAL AND HYDROLOGICAL FEATURES From Medallandssandur to Ingólfshöfdi to the coast opposite the Hali farm, the coastline can be seen faintly, although the terrain is still quite dark where no snowfall increases the re- flectivity of the land. The snowline can be seen on the upper parts of the snout of Skeidarár- jökull and on the higher elevations of the Eldhraun and Medallandssandur areas. The demarcation line between snow cover and bare ground reflects the air temperature on 31 January 1973 and also represents the 0°C iso- therm relative to elevation after a recent heavy snowfall. Two weather stations in the Icelandic Weather Bureau network fall within the area of the image, Kirkjubæjarklaustur and Fagur- hólsmýri, 45 km southwest and 30 km south- east of Skeidarárjökull, respectively. Weather records from the Icelandic Weather Bureau show that both Kirkjubæjarklaustur and Fagurhólsmýri experienced heavy precipitation (26.2 mm and 27.2 mm, respectively) in the form of rain on 29 and 30 January 1973. Such precipitation would increase in amount at higher elevations and be in the form of snow. The weather turned colder at both stations after passage of the storm. At Kirkjubæjar- klaustur the air temperature was — 3° C at the time of satellite passage on 31 January 1973 (Sigtryggsson, H., 1973, personal commun- ication). The lack of snow cover on the snout of Skeidarárjökull indicates that this glacier is ablating to some degree in midwinter, dur- ing the coldest montli of the year. The same probably holds true of the snout of Skafta- fellsjökull, Svínafellsjökull, and Breidamerkur- jökull, although it is difficult to tell because of the darkness and cloudiness at the loca- tion of the latter. According to Eythorsson 4 JÖKULL 23. ÁR and Sigtryggsson (1971), for the period 1931— 1960 the average temperature isotherms for January in this part of Iceland are 0° C for the coastline and — 1 ° C for the southern margin of the Vatnajökull. [The mean tem- perature (1931—1960) for January for Kirkju- bæjarklaustur and Fagurhólsmýri is — 0.4° C and 0° C, respectively]. Although botli weather stations have the 3rd and 2nd highest mean annual precipitation (1931—1960) of weather stations in Iceland, 1725 mm and 1761 mm for Kirkjubæjarklaustur and Fagurhólsmýri, respec- tively, they are also subject to frequent thaws because of their proximity to the warmer ocean waters to the south. For the period 1931—1960, for two-thirds of the month of January Fagur- hólsmýri lacked a measurable snow cover. The three largest fresh-water lakes in the image are frozen and snow-covered: Thóris- vatn, Langisjór, and Grænalón. The position of the glaciers on the western and eastern part of Grænalón, particularly the steep edge of the ice dam on the east, can be clearly seen. The flat snout of the western glacier tongue contrasts sharply with the steeper calving front of the eastern glacier tongue because of its position in the lake. Several flowing streams and rivers are evi- dent in the image including the following: streams from the snout of Skeidarárjökull, Sand- gígjukvísl, Skeidará, and Súla; Núpsá, Skaftá, Djúpá, Hverfisfljót, and Hólmsá and north of Vatnajökull, Jökulsá á Fjöllum. It would seem that a study of ERTS-1 imagery of Iceland during the late winter and early spring, parti- cularly whether or not rivers are flowing or frozen, can give a qualitative measure of the climate in the more remote areas of Iceland. APPEARANCE OF SNOW-COVERED TERRAIN AND ICE FEATURES Under the low angle (7°) of solar illumina- tion the uneven surface of Vatnajökull becomes strikingly apparent. Every minor irregularity, depression, nunatak, or other morphologic fea- ture of the surface of the icecap is strikingly displayed. How many of the depressions and higher areas are caused by subglacial topo- graphy or are structurally controlled and how many depressions are the result of subglacial

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