Taupo eruption took place in New Zealand? — In the northwest Greenland Camp Century deep core no visible layer was observed (This core suffers from severe thermal shock, due to drill- ing, at these depths and acidities cannot be mea- sured, but a visible layer would anyway be seen if present). There are other complications: The visi- ble banding, which contains the largest particles (aggregates of some 100 pm) concludes the period of high dust level, which is peculiar if the layer derives from a volcanic eruption, as one would expect the largest particles and highest concentrations to occur in the beginning of the period due to gravitational settling. Indication of melting was present in the visible layer, which may explain the presence of large aggregates. The microprobe data do not lend support to the idea, that the layer contains large amounts of cosmic dust. The layer could well be interpreted as being due to continental dust as suggested by Froggatt (1981, p. 491), but the composition could not arise from e.g. forest or bush fires (Froggatt 1981, p. 491). Was the layer due to unusual meteorological conditions in 174—175 A.D. or due to an indirect effect of a cosmic body? The phenomenon stirs the imagination, even if it in the end proves to be, what it looks iike i.e. a statistical anomaly in the northern hemisphere environmental and meteorological system. That the ice layer is dated to within the time period of emperor Ling Ti’s reign suggests, that the corres- ponding high dust concentration in the air was not just a Greenland phenomenon, but for the moment we do not know what caused it and how widespread it was. HIGH ACIDITY LAYERS IN THE DYE 3 CORE AND SINGLE ERUPTIONS In Fig. 1 is shown the acidity along the Dye 3 deep core. As the data treatment of the Dye 3 acidity has not yet been finished the average acidity over Holocene has been given as approx. 1,2 pequiv. H+/kg of ice. The pre-Holocene ice (below 1786 m from surface) is in general slightly alkaline, which prevents detection of volcanic eruptions by the acidity method. The volcanic acidity signals, shown as peaks on the figure, are for practical reasons exaggerated with respect to the depth interval they cover. The peaks give the average acidity over the year of maximum acid concentration from a particular large eruption. Only values larger than approx. 4 pequiv. H+/kg (preliminary estimate) have been shown in order to ensure, that the values are well above the natural non-volcanic acid background. The background is of course not constant, as shown in the figure, but its variation is well below the 4 pequiv. H+/kg. Summer melting or high temperatures in the Dye 3 region during a few days of summer (some + 5°C) can cause high acidities, which are not related to volcanism. Usually the melting and warm temperatures only influence the acidity over some 10—20% of an annual layer and the yearly average acidity will still be well below 4 pequiv. H+/kg. In a few cases the ice core contained strong percolation paths i.e. refrozen meltwater along an irregular vertical path, which by chance was confined within the core. The percolated meltwa- ter usually refreezes, when it reaches the pre- vious denser and colder winter snow, and is seen as percolations in the core more or less like a meltlayer. The presence of percolation paths in the ice core is easily seen, when the annual layers are not too thin. Only 3 such paths, which in fact showed high acidities, are left out of the figure. There is a chance, that a large eruption has marked the ice with high acidity in the annual layer where such a percolation path is present, but it is not likely to occur, because in Fig. 1,20 peaks are shown over a period of approx. 10,000 years and only 3 high acidity peaks had to be left out. The peaks shown in Fig. 1 are therefore, most probably, all due to volcanic eruptions. The Dye 3 acidity profile is ideal with respect to continuity and details along the core. The entire core was measured in the field, mm by mm, and a core recovery better than 99.9% secures, that no strong acidity layers were lost e.g. due to missing ice. The Dye 3 location, or for that matter South Greenland, is not the best place to detect acid fallout from volcanic eruptions, as fission product profiles over the period 1953-1965 show almost half the concentrations of more northerly loca- tions, while the acid non-volcanic background is nearly the same as e.g. in North- and Central Greenland. This is due to a generally higher precipitation at South Greenland latitudes (over the entire hemisphere) combined with a stronger 54 JÖKULL 34. ÁR

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