Wind erosion One of the things that surprises foreign geologists visiting Iceland is the great role played by wind erosion in this oceanic island with its humid cold- temperate climate. It is estimated that since the beginning of settlement at least 20.000 km2, or nearly 50% of the area then vegetated, has since been deprived of its soil cover by wind and water. Birch woods covered at least 20.000 km2 eleven centuries ago, nów only about 1.200 km2 remain. Opinions have differed as to the main cause of the destruction of the birch woods and the soil erosion by wind and water. Some students of the problem have put the blame. mainly on deteriorating climate and volcanic activity. Others have main- tained that man and his grazing livestock are the main cause. With the aid of dated tephra layers it has been possible to measure the rate of thickening of the soil cover and this rate is an indicator of the soil erosion going on, as the windborne material is partly deposited on the vegetation covered areas and bound by the vegetation. The diagram in Fig. 4 is a typical one. It is based on a soil profile from which have been extracted the tephra layers which are not part of the thickening of the loessial soil as such. Up to a certain point on the diagram the rate of thickening is rather even, although increasing somewhat with the climatic deterioration at the beginning of Subboreal time about 500 B. C. But a great increase comes shortly after the arrival of man and his livestock to this isolated country which before that time had no grazing mammals. Tephrochronological correlation Because of the limited size of Iceland much of the tephra produced there is deposited on the ocean surrounding the country. Ocean currents occasionally carry Icelandic tephra to distant shores. Airborne tephras from Iceland have been identified in peat soils in Scandinavia, among them the light Hekla layers H3 and H4, Cl4-age respec- tively about 4000 and about 2800 years. Measuring of the O16/18 ratios has enabled dating of cores from the Greenland ice more than 100.000 years back- wards in time and for the last one and a half mil- lenium the dating is exact almost to the year. Ice layers of high acidity, due to the fallout of aerosols from large eruptions in the past, can be detected by measuring the electric conductivity of melted samples. One of the first eruptions so detected was the Lakagigar eruption of 1783. Among other Ice- landic eruptions detected is a very big eruption in 934 A. D., which almost certainly is the eruption that formed the great chasm Eldgjá. Tephrochro- nological teleconnections have now become global and enable exact datings reaching backwards in time far beyond written records in many volcanic areas. SELECTED REFERENCES Friedman, J. D., C. E. Johansson, N. Oskarsson, H. Svensson, S. Thorarinsson and R. S. Williams, 1971: Observations on Icelandic polygon sur- faces and palsa areas. Photo interpretation and field studies. Geogr. Ann. Stockh. 53. Ser. A: 115—145. Hammer, C. U., 1979: Acidity of polar ice cores in relation to absolute dating, past volcanism and radioechoes. Journ. Glaciol. (in press). Persson, Chr., 1966: Försök till tefrokronologisk datering av nágra svenska torvmossar. (Attempt at tephrochronological datings of some Swedish peat bogs). Geol. Fören. Stockh. Förh. 88: 361 — 394. Steinthorsson, S., 1977: Tephra layers in a drill core from the Vatnajökull ice cap. Jökull 27: 2—27. Thorarinsson, S., 1944: Tefrokronologiska studier pá Island. (Tephrochronological studies in Ice- land). Geogr. Ann. Stockh. 26: 1 —127. Thorarinsson, S., 1962: L’érosion éolienne en Islande a la lumiere des études tephrochrono- logiques. Rev. Géomorphol. Dynamique 13: 107 — 134. Thorarinsson, S., 1967: The eruptions of Hekla in historical times. The eruption of Hekla 1947 — 1948 I. Soc. Sci. Islandica: 170 pp + 13 Pl. Thorarinsson, S., 1970: Tephrochronology and medieval Iceland. In Beyer, R. (Ed.): Scientific Methods in Medieval Archaeology: 295 — 328. Univ. of California Press. Westgate, J. A. and C. M. Gold (Eds.), 1974: World bibliography and index of Quaternary teph- rochronology: 528 pp. Printing Service Depart- ment. The University of Alberta. 36 JÖKULL 29. ÁR

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