Fig. 4. Typical temperature profiles from deep drillholes inside and outside geothermal areas in Iceland. Kaldársel is within the active volcanic zone but far away from high temperature areas and shows nearly zero thermal gradient down to about 700 m. Holes in the Westman Islands and Akranes show thermal gradients nearly undisturbed by water convection. Laugaland LJ-8 and Reykjavik G-4 are typical for production holes in low tem- perature areas, whereas the holes Krafla and Krísuvík are in high temperature areas. (Slightly modified from Pálmason et al. 1978). HIGH TEMPERATURE AREAS According to the plate tectonics theory the highest heat flow on a constructive plate margin should be along the volcanic zone, which is the surface expression of the plate boundary. This is not always apparent on the surface as recent vol- canics are normally highly pervious and cold groundwater percolates deep into the surface for- mations. In one drillhole in the volcanic zone of SW-Iceland a zero thermal gradient was encount- ered down to 700 m. With increasing compaction of the strata and sealing by precipitation from warm water the geothermal gradient increases with depth, and it is likely that magmatic temperatures (1000—1200°C) prevail at 10 km depth or less un- der the entire volcanic zone of Iceland. The high temperature areas are like chimneys that extend from the hot zone below and all the way to the surface. The high temperature areas are always associated with volcanotectonic features such as volcanic fissure swarms or more commonly central volcanoes with intermediate and acid volcanics, fault swarms, and sometimes calderas. At such sites there is a great abundance of dykes, sheets and other minor instrusions cooling at a shallow depth in the crust. These intrusions, in addition to the general heat flux of the volcanic zone, form the heat source for the hot water convection systems of the high temperature areas. The mineral content of the water increases with its temperature. Precipitation of mainly silica and calcium carbonate occurs where the high temperature water meets cold groundwater. This seals the hot water cell off and with time allows it to extend up through the per- vious surface formations. Several new high temperature areas have been identified with increasing research during the last decade. To date there are considered to be 22 cer- tain and 3 potential high temperature areas in the country. The surface manifestations are in the form of steam holes, boiling mudpools and highly altered ground. The high temperature areas vary greatly in size and have an aggregate coverage of about 500 km2. Three areas cover approximately 100 km2 or more, but the bulk of the areas are 1 — 20 km2. The size of the individual high temperature areas is a function of the age of the systems, the extent of the magmatic heat source and the lithology and struc- ture of the strata in which the high temperature convection systems are formed. The total natural heat discharge of the high temperature areas is poorly known, but has been estimated at about 4000 MW. The heat exchange between the intrusives and the meteoric water can to some extent be inspected in the deeply dissected roots of Tertiary and Plio- Pleistocene central volcanoes. These are charac- terized by a great abundance (locally 50— 100%) of minor intrusions. Centrally inclined sheet swarms (cone sheets) have been found in the majority of dissected central volcanoes investigated to date in Iceland. The sheets are commonly 1 — 2 m thick. Minor dolerite, gabbro and granophyre intrusions are also common. The host rock is intensely altered and the cores of the central volcanoes are charac- terized by a cupola of propylitized rocks which delineates fhe shape of the extinct high tempera- ture convection system. The outer part of the aureole is characterized by quartz and platy calcite, but these minerals are accompanied by laumontite 52 JÖKULL 29. ÁR

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