Achim A. Baylich Whereas the Dalatangi meteorological station records mean monthly temperatures exclusively above freezing point, the number of months reveal- ing mean temperatures below freezing point distinctly rises with increasing altitude. For instance, at an alti- tude of 300 m a.s.l. mean monthly temperatures above 0ÆC are found only from May until November, at 600 m a.s.l. from May to October and at 900 m a.s.l. only from June to September. The general increase of the air temperature from April-May onwards manifests it- self in the lower parts of the study area in the begin- ning of the main snow melt period. In the upper areas, temperatures, while increasing, remain below freez- ing. Accordingly, snow cover has a longer duration. In shaded areas snow patches and fields exist all year long. At the Dalatangi meteorological station, frost events are generally recorded for the first time at the end of September or in October. The last frost events normally occur between end of April and be- ginning of June. At 300 m a.s.l., the frost period lasts from September-October until June, at 600 m a.s.l. from September-October to June-July. At 900 m a.s.l., there is no month which is free of frost (Beylich 1999a; 2000c). Frost days are mostly and normally recorded from November to April. From a morphoclimatic point of view, it has to be emphasised that the lower parts of the study area have shorter frost phases interrupted by phases which are free of frost (Figure 7), whereas the upper areas are characterized by frost phases last- ing several months from November until April-May at (600 m a.s.l., and from October to May-June at 900 m a.s.l., (Figure 8) (Beylich 1999a; 2000c). Fur- thermore, the altitude-related increase of frost days mainly implies an increase in the number of ice days, whereas the frequency of freeze-thaw days only in- creases up to an altitude of 300 m a.s.l. While Febru- ary, March and April are the months with the highest number of freeze-thaw days at Dalatangi, these are the months of January, February, and April at 300 m a.s.l., April, May and November at 600 m a.s.l., and May, June and October at 900 m a.s.l. The minimum air temperatures on freeze-thaw days are seldom below -5ÆC, with the daily freeze-thaw events normally be- ing confined to the near-surface substrates. During the field research period, minimum air temperatures of - 5.8ÆC on freeze-thaw days did not lead to frost pen- etration into the ground to depths of 5 cm (Beylich 1999a). Information on frequencies and intensities of frost events to be expected in different months at differ- ent elevations a.s.l. can be gained by the magnitude- frequency analyses shown in Figure 9. Even at higher altitudes frost intensities in Austdalur are far from reaching the levels recorded at Latnjavagge (see Fig- ure 6). It can be assumed that frost weathering is en- hanced during longer and more severe frost spells (Schunke 1975; Church et al. 1979; Washburn 1979; Walder and Hallet 1985; 1986; Hallet et al. 1991; Matsuoka and Sakai 1999). This assumption is sup- ported by the fact that frost weathering and rockfall activity from rockwalls in the study area becomes more intense with increasing altitude a.s.l. (Beylich 1999a). Another indication is the seasonal variabil- ity of rockfall activity at basalt rockwalls situated at an altitude of 450 m to 750 m a.s.l. Here the highest rockfall activity occurs after the winter frost period that lasts several months (Beylich 1999a). The duration of frost periods is also important for the intensity of chemical weathering and for fluvial channel discharges. Numerous and long lasting frost spells decrease the intensity of chemical weathering, which is in any case small due to the subarctic mor- phoclimate (Beylich 1999). Also geomorphologically relevant is the lowering of channel discharges during frost spells. Daily freeze-thaw events imply the forming of needle ice at convex, vegetation- and snow- free, soil covered slope surfaces exposed to the wind in autumn and winter. Field work in Austdalur showed that even slight night frosts may cause the formation of nee- dle ice (Outcalt 1971). The formation of ice crystals causes the substrate to break up and dry and solids are lifted. Thus a large number of freeze-thaw days favours the deflation of fine material and the destruc- tion of vegetation cover by turf exfoliation. Due to heaving of particles at vegetation free and inclined slope areas, needle ice has a direct denudative ef- 42 JÖKULL No. 52, 2003

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