Diamictite units 11 and 12 in the Hvalfjörður area are separated from the underlying tillites by approxi- mately 100 m of olivine tholeiite lavas and appear in sections in the Litla Botnsá gully and in the Brunná gully (Figs. 3 & 7d). These diamictite units have the same lateral extent as the previous two glacial de- posits (diamictite units 9 and 10) and display almost identical facies associations, i.e. basal tillite asso- ciated with both slump deposits and thick lacustrine sediments, beside thick and laterally extensive hyalo- clastite sheets. The uppermost diamictite unit under discussion here crops out in the form of a brecciated hyaloclastite and tuffaceous sandstone and appears approximately 100 m higher within the stratigraphic section. IMPLICATION OF THE GLACIAL DEPOSITS OF THE UPPER BORGAR- FJÖRÐUR AND HVALFJÖRÐUR AREA Lithofacies analysis of interbedded diamictites in the upper Borgarfjörður area and the Hvalfjörður area reveals repeated glacial advance and retreat. Five major glacial advances are recognized in the upper Borgarfjörður section and at least six glacial advances are recognized in the Hvalfjörður area within the time- span under discussion (3.1 Ma-1.8 Ma). The impli- cations of the glacial lithofacies as climate indicators are however severly limited. A glacial deposit, such as melt-out or lodgement tillite, in a given sequence, is an evidence of a glacial activity in that area, but it offers very little information about the duration and gives only the minimum extent of the glacier advance. A chronological context and a meaningful compari- son between areas is necessary in order to evaluate the regional significance of these glacial events. A correlation between sections of the upper Borg- arfjörður area and the geopolarity time scale is based on several K/Ar dates (McDougall et al., 1977). The combined data indicate that the sequence is virtually continuous from the early Matuyama back to the base of epoch 6 and into epoch 7 (McDougall et al., 1977). Correlation between sections around the Hvalfjörður area is based on the results from magnetic polarity measurements and supported by few K/Ar dates, from the mountain Akrafjall (3.12-2.87 Ma, this study) and from the top of the mountain Esja (1.8 Ma, Kristjáns- son et al., 1980). Composite stratigraphic columns of the two areas show at least seven reversals of the Earths magnetic field during the time the volcanic rocks of the region were erupted. The base of both stratigraphic successions has been correlated to the base of the Mammoth reversed polarity event of the Gauss epoch the youngest strata discussed here are thought to precede the Olduvai normal polarity event (Kristjánsson et al., 1980). Based on these data, a tentative correlation and speculations of the inferred glaciations within the areas can be made. The published K/Ar dates from the Borgarfjörður area in conjunction with the palaeomagnetic polar- ity data from the lavas show that the volcanism in the region was virtually continuous between about 7.0 and 2.0 Ma. A linear regression analysis based on 22 K/Ar dates was used to assign dates to the strati- graphic column (McDougall et al., 1977). By adopt- ing the regression equation, it is possible to infer the approximate age of the first glacial horizon identified within the area (Fig. 8). In constructing the regression equation, the accumulation rate was assumed constant. Although this approach is unlikely to be completely correct as pointed out by McDougall et al. (1977), it can be used to obtain age estimates. The regression equation McDougall et al. (1977) used is: y = 6.72-0.001348® where y is the age in million years and x is the height in metres above the base of the section. Using this equation a calculated age of 2.6 Ma for the first identi- fied glacial deposit was obtained. If the same method is applied to the fourth glacial deposit (diamictite unit 9) in Borgarfjörður, a calculated age of 2.07 Ma is obtained. This suggests that the four diamictites iden- tified as glacial deposits are distributed over approx- imately 500,000 years. The fifth and last glacial unit recognized in the area is not included in the regres- sion analysis because of the unconformity between the fourth and the fifth glacial deposit. If the linear regression analysis derived from the K/Ar dates in Borgarfjörður is valid, and the calculated age for glacial deposit 4 (diamictite unit 9) is reason- 18 JÖKULL,No. 40, 1990

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