line normative they have been referred to the alkalic magma series whilst those of the Eyjafjöll complex have been taken to relate to the transitional alkalic magma series. However, this latter assessment was based on very limited data and there is clearly a need for further analysis of rocks from the Eyjafjöll volcanic system. GENERAL DISCUSSION The preponderance of palagonite tuff-breccias in Units A-E suggests that probably all the volcanic rocks in the Sólheimajökullareaand immediate vic- inity were erupted in Pleistocene to Recent times. The presenceofglaciated erosion surfaces and tillit- es within the volcanic successsion supports the commonly, although not universally, held view that the palagonite tuffs-breccias and associated basalt pillows, lobes or more massive flow-units are largely the products of sub-glacial eruptions. However, at least the lower part of Unit C appears Iikely to have been erupted during an inter-glacial period. Possible feeder dykes for the eruptions are rarely seen in the Sólheimajökull area; hence there is no direct evidence of the precise position and orient- ations of the fissures from which these rocks were presumably erupted. On balance it seems likely that in this area one is in general observing rocks, which represent the distal portions of volcanic eruptions. However, itis noteworthy that twodykes crosscutting Units B-E on Skógafjall and Hvítmaga have roughly E-W trends, similar to the trends of recent fissure eruptions in the col area between the Eyjafjallajökull and Mýrdalsjökull ice caps. On lithological grounds it is tempting to correlate all the rocks in the area mapped with the Moberg Formation (sensu stricto). No undoubted pre- Pleistocene “plateau-type” lava flows exist in this area. However, the distinctive, coarsely porphyritic ankaramite of Unit A apparendy correlates litho- logically and perhaps also in a time-stratígraphic sense with rocks elsewhere in south-central Iceland (notably at Hvammsmúli and Arnarklettur) which have been previously classified as Old Grey Basalts. However, more recently Jakobsson (1979) has inter- preted all the ankaramites associated with the Eyja- fjöll volcanic system to be of Upper Pleistocene age. We certainly see no justification for classifying the volcanic rocks in the canyon sequence to the west of the Jökulsá river as Old Grey Basalts - as indicated on the Geological MapofSouth-East Ice- land (Kjartansson 1962). Our mapping has shown that these rocks are younger rather than older than most of the rocks immediately to the east of the Skógafjallsgil and Jökulsá river. Neither could we see any real justification for the recognition of the rocks west of the Skógafjallsgil river and from just the north of the area mapped in detail up to the col between Eyjafjallajökull and Mýrdalsjökull as Pleistocene Young Grey Basalts (Kjartansson 1962). We consider that these rocks laigely correlate with Units D and E to the east of Skógafjallsgil. These rocks to our mind suffered considerable erosion prior to the deposition of the “Top” conglomerate, the latest glacial tillite. The crude trap featuring sometimes apparent on the ridge tops in this area has resulted from the relative resistance to glacial erosion of the more massive basalt flow-units within the “Moberg” succession, such as the capping bas- alt flow-units of Unit D. However, the deeply incis- ed river courses show that palagonite tuff-breccias dominate the thickening volcanic succession right up to the col, and even the most recent eruption products there. The indication of a gradual change in the chem- istry of the basalt magma type erupted in the Sól- heimajökull area during the Pleistocene-Recent time period is of considerable petrogenetic interest, especially in the light of the evidence both from Iceland (Jakobsson 1972) and the Mid-Atlantic Ridge at 45°N (Aumento 1967) that the nature of the basalt magma type erupted varies with distance from the actíve spreading ridge crest.Furthermore the rate of discharge of volcanic rock appears to decrease with distance from the active ridge crest (Jakobsson 1972). Thus large volumes of tholeiitic basalt characterise the active spreading ridge crest and progressively smaller volumes of first transi- tional alkali basalts and finally alkali olivine basalts as one moves across the ridge flanks. From this it seems reasonable to expect that the basalt magma type erupted in a particular area may become in- creasingly alkaline in character with time as the site of eruption moves progressively away from the act- ive spreading ridge crest. The foregoing observat- ions and data on the volcano-stratigraphy in the Sólheimajökull area are consistent with such a model, as indeed are data on the Vestmannaeyjar volcanic system (Jakobsson 1979) where earlier transitional alkali basalt suite magmas have been followed by genuine alkali olivine basalt suite magmas in more recent times. 70 JÖKULL 33. ÁR

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