Morphoclimates and morphodynamics of the northern Swedish Lapland and east Iceland tively low. In July, August and September they give rise to low channel discharges, with smaller creeks drying up completely (Beylich 1999a; 2000c). MORPHOCLIMATE AND PRESENT-DAY MORPHODYNAMICS IN LATNJAVAGGE AND AUSTDALUR A quantitative recording and labelling of present-day morphodynamics of Austdalur is possible after cal- culating the sediment budget of the drainage basin (Beylich 1999a; 1999b; 2000a; 2000b; 2003). The dominance of aquatic slope denudation over chemi- cal denudation is due to the low intensity of chemical weathering, to the relatively high share of vegetation- bare slope surfaces, and to the mobility of channel debris beds in the very steep drainage basin. The very high wind speeds cause a further expansion of the vegetation-bare surfaces. The process which is third most important regarding annual mass transfer [t m yr ] are ground avalanches, followed by rock- falls/boulder falls, creep processes, debris slides and flows and deflation. High amounts of runoff may oc- cur all year long. Annual mass transfers in the main channels clearly dominate over slope processes, with the fluvial transport of solids being more important than the transport of dissolved salts. The intensity of the processes active in the present periglacial mor- phoclimate is altogether low (Beylich 1999a; 1999b; 2000a; 2000b). The hydrological regime in Latn- javagge is very different from Austdalur, with flu- vial discharge and general forming activity being lim- ited to the period from middle/end of May to Octo- ber/November. Permafrost exists at least sporadically in the area (Kling 1996; 2003; Beylich et al. 2003). Slush flows, triggered by rapid snow melt in early summer, are an important process. Because of the al- most complete and very stable vegetation cover and the stability of fluvial step-pool systems in the less steep drainage basin slope wash processes are much less important than in Austdalur. Although the in- tensity of chemical weathering is low, chemical de- nudation is more important than mechanical fluvial denudation (Beylich 2001a; Beylich et al. 2003). The intensities of the geomorphological processes active in this periglacial environment are also low. In both periglacial environments Holocene modification of the glacial relief is negligible (Beylich 2001a; 2003; Beylich et al. 2003). CONCLUSIONS The characteristics of the present-day morphoclimates control the type and intensity of geomorphologic pro- cesses in Latnjavagge and Austdalur. The comparison of the different periglacial environments provides in- formation on controlling factors of the processes and sediment budgets in the areas. Similar studies to the present one carried out in other periglacial environ- ments having different morphoclimates seem to be worthwhile in order to obtain a better understanding of the importance of the prevailing wind, temperature and precipitation regimes for the current geomorpho- logic processes, sediment budgets and trends of relief development. They would also provide a more re- liable evaluation of possible geomorphologic effects of predicted (morpho-)climate changes (Barsch 1993; Schlyter et al. 1993; Rapp 1995; Beylich 2001b; Beylich 2003). Acknowledgements Field work in East Iceland was carried out within the framework of a Graduierten-Stipendium of Bun- desland Sachsen-Anhalt, Germany, 1996–1998. The four field campaigns in Iceland were financially supported by Deutscher Akademischer Austauschdi- enst (DAAD), Bonn. Research in Swedish Lapland was carried out within the framework of a Post- Doc-grant given by Deutscher Akademischer Aus- tauschdienst (DAAD), Bonn: Post-Doc-Programm, HSP III (Stipendium des DAAD im Rahmen des Gemeinsamen Hochschulsonderprogramms III von Bund und Ländern, 1999–2001, grant to Achim A. Beylich). Since 2002 research has been funded by the Deutsche Forschungsgemeinschaft (DFG, Bonn, Emmy Noether-Programm, grant to Achim A. Beylich). This paper was written in the Physical Geo- graphy Programme of the Department of Earth Sci- ences, Uppsala University. Meteorological data were made available by Úrsúla E. Sonnenfeld and Trausti Jónsson (Icelandic Meteorological Office, Veðurstofa JÖKULL No. 52, 2003 51

Blaðsíða 1
Blaðsíða 2
Blaðsíða 3
Blaðsíða 4
Blaðsíða 5
Blaðsíða 6
Blaðsíða 7
Blaðsíða 8
Blaðsíða 9
Blaðsíða 10
Blaðsíða 11
Blaðsíða 12
Blaðsíða 13
Blaðsíða 14
Blaðsíða 15
Blaðsíða 16
Blaðsíða 17
Blaðsíða 18
Blaðsíða 19
Blaðsíða 20
Blaðsíða 21
Blaðsíða 22
Blaðsíða 23
Blaðsíða 24
Blaðsíða 25
Blaðsíða 26
Blaðsíða 27
Blaðsíða 28
Blaðsíða 29
Blaðsíða 30
Blaðsíða 31
Blaðsíða 32
Blaðsíða 33
Blaðsíða 34
Blaðsíða 35
Blaðsíða 36
Blaðsíða 37
Blaðsíða 38
Blaðsíða 39
Blaðsíða 40
Blaðsíða 41
Blaðsíða 42
Blaðsíða 43
Blaðsíða 44
Blaðsíða 45
Blaðsíða 46
Blaðsíða 47
Blaðsíða 48
Blaðsíða 49
Blaðsíða 50
Blaðsíða 51
Blaðsíða 52
Blaðsíða 53
Blaðsíða 54
Blaðsíða 55
Blaðsíða 56
Blaðsíða 57
Blaðsíða 58
Blaðsíða 59
Blaðsíða 60
Blaðsíða 61
Blaðsíða 62
Blaðsíða 63
Blaðsíða 64
Blaðsíða 65
Blaðsíða 66
Blaðsíða 67
Blaðsíða 68
Blaðsíða 69
Blaðsíða 70
Blaðsíða 71
Blaðsíða 72
Blaðsíða 73
Blaðsíða 74
Blaðsíða 75
Blaðsíða 76
Blaðsíða 77
Blaðsíða 78
Blaðsíða 79
Blaðsíða 80
Blaðsíða 81
Blaðsíða 82
Blaðsíða 83
Blaðsíða 84
Blaðsíða 85
Blaðsíða 86
Blaðsíða 87
Blaðsíða 88
Blaðsíða 89
Blaðsíða 90
Blaðsíða 91
Blaðsíða 92