whether the compared annual layers are exactly corresponding. No date have been given for these events in Fig. 2, because it would give a false impression of the dating accuracy. This has, how- ever, little importance for the R ratios, as the annual Dye 3 acidities around these dates are quite low and high values of R will in any case be the result. The 1360 signal may not be due to an eruption, as it is one of the annual layers in the Dye 3 core, where a possible influence of high summer tem- peratures and/or meltlayers is suspected, though not proven. The date has been set in brackets in Fig. 2 and the “event” will be left out of the discussion. The 516 event cannot be compared to a similar event in the Camp Century core as the latter core is not usable for acidity measurements around this age. The missing indications, in the Dye 3 core, of 3 volcanic signals are not too surprising, because such signals should in general be Iower than in the Créte core i.e. in some cases too low for definite detection. Still it is peculiar, that the R values are as high as 4.7, 7.1 and 3.8 for the 3 eruptions. The R value for fission product con- centrations (total (3 activity) is 1.8, but the fission product profile was caused by a “mess” of nuclear detonations at various latitudes, while we are here considering individual eruptions which took place at specific geographical positions. As can be seen in Fig. 2, some Icelandic eruptions show fairly low values of R. It seems, that Icelandic eruptions are favorably located with respect to high acid deposition on Greenland. This is not a very surprising finding. However, one could not have known “a priori”, that the Dye 3 core in some cases would show higher acidities, than the Créte core, but for Eldgjá, the R value is higher than the fission product value. If the average R value for those eruptions, which exceeds approx. 4 pequiv. H +/kg in both cores is calculated, it comes out as 1.7, i.e. pretty close to the R= 1.8 for the fission products. Even though the data mentioned above are limited, they do give a hint for an interpretation: The eruptions in 1642, 1602 and 623 took place in the northern hemisphere, the debris drifted northward, but in general the gaseous products did not disperse widely over the hemisphere. Perhaps they were moderately strong eruptions in e.g. Japan, Alaska or Kamchatka. This interpretation is further supported by the Katmai 1912 eruption, which is clearly marked in ice cores from several locations in Mid- and North Greenland, but is only just detectable in the Dye 3 core (not shown in Fig. 2, because the average acidity is too small). If the above holds to be true, we have the possibility of classifying the eruptive signals into 3 groups: 1) Icelandic eruptions 2) Northern hemisphere eruptions north of ca. 50° North. 3) Eruptions south of ca. 50° north. If acidity profiles from Antarctic deep cores are available, there is the further possibility, that we can distinguish between the eruptions south of ca. 50° north: If a high signal occurs within the same time period (a few years) in both the Green- land and Antarctic profiles, the eruption most probably took place in the equatorial region. In fact, there is such a candidate i.e. the 1259 event, which recentiy has been identified in both the South Pole and the Byrd core (not published; but dating and assessment in progress, Clausen and Hammer, in preparation) With these remarks I have deviated somewhat from Icelandic eruptions, so Iet me return to the individual acid signals of an Icelandic origin. SOME ICELANDIC ERUPTIONS The Lakagígar eruption This famous Icelandic fissure eruption started at June 8th, 1783 and has been described in detail by Thorarinsson (1969). The eruption was mainly a lava eruption and is estimated to have produced a total of 12.5 km3 material — measured in lava equivalents. It left the Greenland Ice Sheet pre- cipitation of 1783 with strongly elevated electrical conductivity mainly caused by high concentra- tions of H2S04, Hammer 1977). While this ice core information on the eruption was obtained by analyzing melted samples, the data presented below resulted from electrical measurements on the solid ice (Hammer 1980b). The electrical current being a function of the concentration of strong acids, independent of the anions. The Lakagígar signal is shown in Fig. 3 for 3 different ice sheet locations. It is the highest yearly aver- age acid signal over the entire Dye 3 core. JÖKULL 34. ÁR 57

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