sheet and the low grade of welding suggest a high eruption column before it collapsed and the ignim- brite sheet was formed (Cas and Wright, 1987). The volume of the Herfell ignimbrite amounts to at least 5 km3. RESULTS OF GEOCHEMICAL AND MICROSCOPIC ANALYSES GEOCHEMICALINVESTIGATIONS In Iceland rocks of tholeiitic, transitional and alkalic character have been found. Rocks of the Tertiary lava pile, however, seem to belong solely to the tholeiitic suite, no alkalic rocks have been discovered so far. Dearnley (1954) described alkalic rocks like crinanite, an olivine and analcite-bearing ultrabasic rock, and trachyte in Loðmundarfjörður. A major goal of the remapping was to take samples of the rocks and to determine their major element content. The rock samples were taken in a recon- naissance fashion rather than for a thorough petro- logical investigation, and the results should be con- sidered accordingly (Tab. I). Rocks with such a low silica content as crinanite have never been found in Iceland, and it is possible that Dearnley did not recognize the secondary character of analcite in the basaltic rocks, thus taking the vesicle-filling analcite as a primary mineral of the rock. Some of the basal- tic rocks have indeed relatively high alkali contents (samples 6 and 7), but crinanite and trachyte have not been found, even though the rock samples were taken as close as possible to the sample points described by Dearnley (1954). Because of their sub- microscopical fine structure rhyolite and dacite lava flows (samples 10 to 13) can only be distinguished with the help of geochemical analyses and calcula- tion of the CIPW norm (Tab. II). Incomplete melting of quartz or a high water content may be responsible for the unusual low totals of the rhyolites. MICROSCOPIC ANALYSES OF THE ROCKS The rhyolites and dacites show vitrophyric or microlitic textures. Macrophenocrysts are pla- gioclase (Anl0-15), sanidine, quartz and opaque oxides. Numerous fractures in the minerals indicate a high viscosity of the lavas. Phenocrysts occur in all three zones of the lava flows and are evenly dis- tributed among them. The structure of the matrix ranges from glassy to microcrystalline. Therefore an exact microscopic description of the minerals is not possible. The glassy matrix has frequently been altered into microcrystalline fan-like or mosaic-like aggregates of those minerals that would have been crystallized out of a slowly cooling magma. Spheru- lites consist of radiating aggregates of alkali feldspar and quartz (Fig. 13). They are the most fre- quent devitrification products. A further structural feature of the matrix is the flow foliation, which is also detectable in the thin sections. The layers represent different degrees of crystallinity, and layering also results from vesicles arranged parallel to the flow. In thin sections the "frozen" movements of a cooling and laminarly flowing melt are visible (Fig. 7). The melt flowed around phenocrysts and thus complicated folds and whirls were frequently created. INTERPRETATION AND CONCLUSION In the remapped area in Loðmundarfjörður pla- teau basalts bank against the silicic lava flows of the Kækjuskörð rhyolitic volcano. No updoming or flexuring of the basaltic rocks in contact to the rhy- olite is visible. The formation of the rhyolite as subaerial lava flows is indicated by ubiquitous auto- brecciation and ramp structures in the rhyolitic rocks. This is interpreted, in contrast to Dearnley (1954), as a small volcano built mainly of Tertiary rhyolite flows. The volcano was subsequently covered by plateau basalts and the Herfell ignim- brite. Silicic rocks in Iceland are mostly confined to central volcanoes, because only here the high output triggers an anatectic melting of crustal material (Oskarsson and others, 1982). The Kækjuskörð rhy- olitic volcano represents an unusual volcanic form and differs from other outcrops of silicic rocks. It formed a volcanic edifice without the typical features of a central volcano, e.g. dyke swarm, cal- dera formation or another kind of downsagging area, but has a much larger volume than eruption products from parasitic vents, e.g. Breiðdalur (Walker, 1963). 86 JÖKULL, No. 39, 1989

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