the area the temperature in an aquifer at 957 m depth is 157°C (Arnórsson et al. 1983). Thus, temperatures overlap with those found in some low-temperature fields. Alteration mineralogy as described by Sig- valdason (1963) indicates higher formation tempera- tures than measured in drillholes at present. Hydro- thermal alteration at depth in the Laugardalur (Reykjavík) and Reykir (Mosfellssveit) low-tempera- ture fields studied by Sigvaldason (1963) and Gunn- laugsson (1977) bears withness of temperatures of around 250”C. Such temperatures may have prevailed some 1 Mya as deduced from geology. At present maximum drillhole temperatures in Reykjavík and at Reykir are 160°C and 100°C, respectively. The evolution of the Reykir system is complicated by the fact that the fossil high-temperature system has drifted into the northeast end of the presently active Kn'suvík fissure swarm. Recent fracturing has, in all likelihood, created secondary permeability. One may speculate that magmatic heat .has been supplied to the system in recent times through lateral dyke injection along the fissure swarm. If this was the case the Reykir low-temperature field would have a magmatic heat source just as is suggested for Borgarfjörður and Upper-Árnessýsla. This discussion on the Reykir geothermal field shows that the history of low-tem- perature systems can be quite complicated and that a smgle model cannot be expected to be applicable to all such systems. In view of the vicinity of the Upper-Árnessýsla geothermal system to the volcanic zone and the young age of the surface formations, it is conceivable that this system represents a cooling high-temperature system. The interpretation of the high hydrogen sul- phide concentrations in the hot springs at Laugarvatn mdicate though that magma is at present replenishing the heat source. The geothermal activity in Reyk- holtsdalur could, on the other hand, hardly represent a cooling high-temperature system due to its distance from the volcanic zone. SUMMARY Review of various geological, geophysical and geochemical studies in the foregoing sections has shown that: 1- The heat output of the Reykholtsdalur and the Upper-Árnessýsla geothermal systems is very large and confined to relatively small areas (50 — 100 km2). It is comparable with that of many high-temperature fields. 2. Dilation seems to be vanishing in the TL-zone and volcanic activity has been limited in post- glacial times. The diminishing tectonic/volcanic activity in the TL-zone is considered to coincide with the southward propagation of the eastern volcanic zone which started about 1 Mya. 3. Several volcanic eruptions have occurred in Upper-Quaternary and Recent times outside the Reykjanes-Langjökull volcanic zone. 4. Near surface thermal gradient on both sides of the Reykjanes-Langjökull zone is higher than pre- dicted by the kinematic volcanic rift zone model of Pálmason (1973). 5. High-temperature geothermal activity is almost absent at present in the TL-zone. 6. The high hydrogen sulphide concentrations in hot spring discharges at Laugarvatn, Upper-Árnes- sýsla, are taken to indicate a magmatic source to the geothermal system. 7. Subsurface temperatures overlapping with those found in some high-temperature fields are indi- cated by chemical geothermometry for a few geothermal systems located in Quaternary and Tertiary rocks flanking the Reykjanes-Langjökull volcanic zone. 8. Flow of water from the central highlands to the low-temperature fields need not be by deep ground water circulation. In some instances the flow could be on the surface. 9. Drillhole data show that some of the low-tem- perature systems are convection systems. The convection is driven by the pressure difference exerted by the hot water column of the upflow and the denser cold water column in the down- flow zone. Hydrostatic head is not required to sustain flow. 10. Alteration mineralogy in a few geothermal systems in SW-Iceland indicates that high-tem- perature systems may develop into low-tempera- ture ones conjuncture with the drifting of the former out the volcanic zone. Based on the above listed results the following con- ceptual models are envisaged for the Reykholtsdalur and the Upper-Árnessýsla geothermal systems: As a consequence of diminishing dilation in the TL-zone magma rising under this zone tends to be diverted into older crust on both sides. Discrete events involving migration of magma batches lead to eruptions or the formation of intrusive bodies. Geothermal systems, like Reykholtsdalur and Upper-Árnessýsla, develop over the intrusions while cooling. In the case of Reykholtsdalur development of strain in the crust has led to relatively recent earth move- ments on already existing faults. The secondary 7

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