approximately 80 kg/s, and the steam flow from a single well ranges up to 25 kg/s at atmospheric pressure. Geysers are active in two high temperature areas in the country at present. Gunnuhver in the Reykjanes field, SW-Iceland, was reactivated in an earthquake in 1967 and erupts at a few minutes intervals to about five meters. The most famous geyser in Iceland is of course the great Geysir in Haukadalur, S-Iceland, which has given name to all erupting springs in the international geological terminology. Geysir has been mostly dormant for the last decades but erupts at least once during most years. Its highest eruptions were up to about 70 m and lasted for about 10 minutes. It has a 20 m deep vertical surface pipe. Measurements show the eruption to originate at about 10 m depth in the pipe. The boiling temperature at that depth is about 120°C, but the water is sometimes super- heated by 5—6°C before it is instantly flashed to steam. The volume of steam at this pressure (depth) and temperature is about seventeen times that of the water and it is the steam explosion that throws the water column above into the air. A small geyser in the Geysir field, Strokkur, was reactivated by drilling in 1963. It erupts every few minutes up to 10—15 m. The first written record of geyser activity in the Geysir field is from annals in 1294 describing earthquakes in the area. GEOTHERMAL UTILIZATION Geothermal energy is very important for the national economy of Iceland as nearly one third of the net energy consumption of the country is from geothermal resources, the other two thirds being nearly equally divided between hydropower and fossil fuel, the latter of which has to be imported. Although hot springs were widely used for washing and bathing through the 1100 years of settlement of the country it was not until in the last five decades that the distribution of hot springs started markedly affecting the distribution of population centres in the country with the growth of villages and school centres built at hot spring localities in the farming communities. Large scale utilization of geothermal for space heating started in the nineteen-forties. At present nearly 70% of houses in the country are geothermally heated. There are about twenty main district heating ser- vices operating with a total installed capacity of about 600 MW, (thermal), the largest of which is the Municipal Heating Service of Reykjavík with about 450 MWt installed. The geothermal water used for space heating is mostly from low tempera- ture areas; the mineral content is low (200—400 ppm) and the water can be used directly. A plant has recently started operating in the Svartsengi steam field where a 240°C brine (% seawater) is used for district heating with the use of heat exchangers. Some of the steam is used for generating electricity for in-plant needs. The present installed capacity is 50 MWt, but will later expand to 100 MWt. A remarkable experiment has been in operation for three years in the Westman Islands where heat is extracted from a thick partly molten lava flow for space heating of a town of 5000 people. About 15% of the houses are now heated in this way, and the system is being extended over the whole town. The heat source (the lava erupted in 1973) is estimated to last at least 15 years. There are nearly 140.000 m2 of geothermal greenhouses used for growing vegetables and flowers; artificial lighting is used on a small scale to lengthen the growing season. Geothermal water and steam is used for various purposes such as fish hatching, fish drying, wool washing, hay drying, and candy making. Industrial utilization on larger scale includes a factory for drying and cleaning of diatomaceous slurry and a factory for drying seaweed for alginate production. A pilot plant has recently been built for extracting salt out of a geothermal brine in the Reykjanes field. Due to the ample hydropower resources of the country electricity has only been produced from geothermal on a small scale as yet. A 60 MWt (electric) power station is at present under construction in the Krafla field in N-Iceland. The project has been seriously affected and delayed by volcanic activity in the area, and the power station is only producing about 6 MWe at present. A 3 MWC power plant operating since 1968 in the Námafjall field had to be closed in 1978 due to volcanic activity. SELECTED REFERENCES Árnason, B., 1976: Groundwater systems in Iceland traced bydeuterium. Soc. Sci. Islandica, 42: 236 pp. Arnórsson, S., 1975: Application of the silica geothermometer in low-temperature areas in Iceland. Am. J. Sci., 275: 763—784. JÖKULL 29. ÁR 55

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