Severe earthquakes occur along the transverse zone. The last major ones in 1784 and 1896 were of magnitude 7—8, and included a sequence of shocks occurring within a few weeks, with the epicenters moving with time from east to west across the 60 km long E-W seismic zone (see chapter 5). The South-Iceland seismic zone might be looked upon as an early stage of opening of an oblique rift axis that eventually will connect the Reykjanes volcanic zone directly to the axial rift zone northeast of the Hekla area. The axial rift zone in northern Iceland connects with the Kolbeinsey Ridge along the Tjörnes Fracture Zone which is a complicated structure made up of both NW-SE trending wrench faults and N-S grabens and volcanic fissure swarms arranged in a dextral en echelon pattern. The total width of the zone from north to south as defined from earthquake distribution is about 70 km. However, geological evidence points to a much narrower zone of true transform character. This is the NW-SE trending Húsavík fault zone which limits the Tjörnes Peninsula to the south. The Húsavík faults are traceable on land for more than 25 km from near the western margin of the axial rift zone to the sea just north of Húsavík, juxtaposing rocks of widely contrasting dips and ages. The Húsavik faults appear to continue towards WNW at least beyond the southern limit of the Grímsey shoal. The shoal platform there is marked by the depth contours clearly tracing deep embayments in the shoal platform close to the coast offsetting the Grímsey shoal to the east relative to the nearest mainland peninsula. Gravity measurements have revealed a very marked low coinciding with the trace of the suspected fault zone in this area indi- cating a sediment filled graben. The rqcks exposed on land nearest to the supposed transcurrent Húsavik faults are tectonically sheared and miner- alized to a degree unknown elsewhere in surface exposure in Iceland. The Húsavík faults are prob- ably associated with tens of km right lateral offset. They formed part of an active transform fault zone during a time interval when a spreading axis lay west of the Grímsey shoal (Fig. 6). The transform motion was greatly reduced about a million years ago when the axial rift zone in northern Iceland extended northwards beyond them along the Ax- arfjördur depression. Young volcanism in the Tjörnes Fracture Zone is unknown outside the fianks of the Axarfjördur depression. An array of volcanic fissure swarms and grabens has been identified between Kolbeinsey and Axarfjördur which presumably formed when spreading on the Grímsey shoal began to wane. The transverse E-W zone across Central Iceland has also been referred to as having transform cha- racter. It extends from Snaefellsjökull eastward across the central ice caps to the Vatnajökull region. The arrangement of fissure swarms and volcanic systems in the area between Langjökull and Snaefellsnes indicates dextral shear. The faults and fissures themselves show that also a component of extension is involved. TECTONICS OF ICELAND AND MANTLE PLUME/HOT SPOT ACTIVITY Hot spots or mantle plumes have been invoked to explain the unusual elevations found across the North Atlantic in the Iceland region. These appear to be transient features of limited and variable ex- tent, and variable in their activity. The scattered subaerial remnants of volcanic rocks defining the Brito-Arctic volcanic province may be considered a manifestation of the plume activity. Several of the gross features of Icelandic geology seem to find a logical explanation if one assumes that a mantle plume exists under Iceland. In par- ticular (1) the elevation of Iceland and the thick- ness of its oceanic crust, (2) the change in strike of the extensional features across Central Iceland, (3) the decrease in intensity of volcanism along the axial rift zones away from South Central Iceland, and (4) the very pronounced offset of the axial rift zones in Iceland relative to the Reykjanes and Kolbeinsey ridges. The elevation of Iceland is a consequence of an anomalous mantle underneath Iceland with lower average densities and higher temperature than the surrounding region. The Iceland crust is more than twice as thick as the normal oceanic crust. Its upper part down to seismic layer 3 (the oceanic layer) is in the order of 4—6 km for an uneroded lava pile compared to about 2—3 km for the average oceanic crust. Both are interpreted as extrusive in origin which implies that the extrusion rate per unit area was about two times greater in Iceland than in the submerged oceanic ridges. A general principle probably controls the change in strike of tectonic elements across Central Iceland. The dyke trend in the older formations shows that this bend in the axial rift zone has persisted throughout the geological history of Iceland. These 26 JÖKULL 29. ÁR

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