Fig. 4 SEM images of tephra particles from the Reykjanes volcanic system tephra layers. Sample numbers refer to Table 1. Length of scale bar 0.1 mm. 4. mynd. Rafeindasmásjármyndir af gjóskukornum úr gjóskulögum á Reykjanesi. Númerin vísa til töflu 1. Lengdarkvarði 0,1 mm. Fig. 5 SEM images of tephra particles from the Reykjanes volcanic system tuff cones Vatnsfell and Karl, and from a subaerial crater belonging to Yngri Stampar. Sample num- bers refer to Table 1. Length of scale bar 0.1 mm. Rafeindasmásjármyndir af gjóskukornum lír gígunum Vatns- felli og Karli á Reykjanesi, ogfrá gíg á landi í Yngri Stömp- um. Númerin vísa til töflu 1. Lengdarkvarði 0,1 mm. from the origin, after which it becomes indistinct. The tephra of the brown layer is more vesicular and more coarse grained than other units of R-3 (Fig. 4). Three samples were analyzed from R-3. The tephra layer R-7 originates from the Karl tuff cone (Fig. 3). Most of the tephra was transported southwards into the sea, and the preservation on land is therefore restricted. The Karl crater is a typical tuff cone built up of alternating base surge deposits and air fall tephra. Pisolites (accretionary lapilli) and firm, highly vesiculated layers are common in the crater rim, indicating that the tephra was saturated with steam when deposited (Fig. 4). The structure of the crater is characterized on one hand by thinly to thick- ly (3 - 30 cm) bedded, massive tephra, and on the other by very thinly to thinly (1-3 cm) planar bedded tephra. Clearly, air-fall and surges have been active si- multaneously during the accumulation of the cone, particularly during the formation of the massive units. Both the Karl cone and the tephra layer R-7 were sampled for analysis in the present study. The Vatnsfell tuff cone which is largely over- lapped by the Karl cone, has a different structure. The Vatnsfell crater rim may be divided into a lower, fine grained, glassy, very thinly bedded part with ripples, and an upper, coarser and upwards coarsening part characterized by scoria and rock fragments. The up- permost unit is nearly pure scoria. The structure of the Vatnsfell cone indicates gradually decreasing access of sea-water to the eruptive vent, and finally, com- plete isolation and strombolian activity. Both major units of the Vatnsfell cone were sampled in the pre- sent study. The Vatnsfell and Karl tuff cones were both formed during the opening phase of the Younger Stampar fissure, which gradually extended into the sea. The Younger Stampar lava flow (H2, Fig. 3) was produced on land by the same eruption, shortly after the cones were formed. The R-9 tephra layer originates from an eruptive site 2-3 km off the Reykjanes coast. The crater has not been preserved. The distribution axis trends NE and the unit is found on the whole Reykjanes peninsula and in adjacent districts (Fig. 1). Possibly, the tephra layer was formed in an eruption that took place in the year 1226 AD, an event that is well documented in JÖKULL, No. 44 45

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