Impact of lake‐level changes on the formation of thermogene travertine in continental rifts: Evidence from Lake Bogoria,Kenya Rift Valley |
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| Authors: | ROBIN W RENAUT R BERNHART OWEN BRIAN JONES JEAN‐JACQUES TIERCELIN CORINNE TARITS JOHN K EGO KURT O KONHAUSER |
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| Institution: | 1. Department of Geological Sciences, University of Saskatchewan, Saskatoon, SK, Canada S7N 5E2 (E‐mail: robin.renaut@usask.ca);2. Department of Geography, Hong Kong Baptist University, Kowloon Tong, Hong Kong;3. Department of Earth and Atmospheric Sciences, University of Alberta, Edmonton, AB, Canada T6G 2E3;4. UMR 6118 Géosciences Rennes, Equipe Dynamique des bassins, Université de Rennes 1, Campus de Beaulieu, Batiment 15, 35042 Rennes cedex, France;5. UMR CNRS 6538 ‘Domaines Océaniques’, Université de Bretagne Occidentale, Institut Universitaire Européen de la Mer, Place Nicolas Copernic, 29280 Plouzané, France;6. National Oil Corporation of Kenya, AON Minet House, Off Nyerere Road, Nairobi, Kenya |
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| Abstract: | Travertine is present at 20% of the ca 60 hot springs that discharge on Loburu delta plain on the western margin of saline, alkaline Lake Bogoria in the Kenya Rift. Much of the travertine, which forms mounds, low terraces and pool‐rim dams, is sub‐fossil (relict) and undergoing erosion, but calcite‐encrusted artefacts show that carbonate is actively precipitating at several springs. Most of the springs discharge alkaline (pH: 8·3 to 8·9), Na‐HCO3 waters containing little Ca (<2 mg l?1) at temperatures of 94 to 97·5°C. These travertines are unusual because most probably precipitated at temperatures of >80°C. The travertines are composed mainly of dendritic and platy calcite, with minor Mg‐silicates, aragonite, fluorite and opaline silica. Calcite precipitation is attributed mainly to rapid CO2 degassing, which led to high‐disequilibrium crystal morphologies. Stratigraphic evidence shows that the travertine formed during several stages separated by intervals of non‐deposition. Radiometric ages imply that the main phase of travertine formation occurred during the late Pleistocene (ca 32 to 35 ka). Periods of precipitation were influenced strongly by fluctuations in lake level, mostly under climate control, and by related changes in the depth of boiling. During relatively arid phases, meteoric recharge of ground water declines, the lake is low and becomes hypersaline, and the reduced hydrostatic pressure lowers the level of boiling in the plumbing system of the hot springs. Any carbonate precipitation then occurs below the land surface. During humid phases, the dilute meteoric recharge increases, enhancing geothermal circulation, but the rising lake waters, which become relatively dilute, flood most spring vents. Much of the aqueous Ca2+ then precipitates as lacustrine stromatolites on shallow firm substrates, including submerged older travertines. Optimal conditions for subaerial travertine precipitation at Loburu occur when the lake is at intermediate levels, and may be favoured during transitions from humid to drier conditions. |
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| Keywords: | Geothermal hot spring Kenya Rift saline lake travertine |
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