DOCSLIB.ORG

Mineral Reactions in the Sedimentary Deposits of the Lake Magadi Region, Kenya

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Mineral Reactions in the Sedimentary Deposits of the Lake Magadi Region, Kenya Mineral reactions in the sedimentary deposits of the Lake Magadi region, Kenya RONALD C. SURD AM Department of Geology, University of Wyoming, Laramie, Wyoming 82071 HANS P. EUGSTER Department of Earth and Planetary Science, Johns Hopkins University, Baltimore, Maryland 21218 ABSTRACT hand, the initial alkalic zeolite that will form in a specific alkaline lake environment cannot yet be predicted with confidence. Among The authigenic minerals, principally zeolites, in the Pleistocene to the many parameters controlling zeolite distribution, the compo- Holocene consolidated and unconsolidated sediments of the sitions of the volcanic glasses and of the alkaline solutions are cer- Magadi basin in the Eastern Rift Valley of Kenya have been inves- tainly of primary importance. tigated. Samples were available from outcrops as well as drill cores. Most zeolite studies are concerned with fossil alkaline lakes. The following reactions can be documented: (1) trachytic glass + While it is generally easy to establish the composition of the vol- H20 —» erionite, (2) trachytic glass + Na-rich brine —* Na-Al-Si gel, canic glass, the brines responsible for the authigenic reactions have + + (3) erionite + Na analcime + K + Si02 + H20, (4) Na-Al-Si long since disappeared. To overcome this handicap, it is desirable gelanalcime + H20, (5) calcite + F-rich brine—> fluorite + C03 , to investigate an alkaline lake environment for which glass as well (6) calcite + Na-rich brine —» gaylussite, and (7) magadiite —• as brine compositions can be determined — in other words, a + quartz + Na + H20. Erionite is the most common zeolite present, modern alkaline lake environment. Such an environment is Lake but minor amounts of chabazite, clinoptilolite, mordenite, and Magadi of Kenya. The Magadi basin is unique because the compo- phillipsite were also recognized. Erionite can form directly from sition and evolution of its waters have been very carefully trachytic glass by the addition of H20 only. It is characteristic of the documented (Eugster, 1970; Jones and others, 1976). Magadi basin because of the low content of alkaline earths in the This paper describes the authigenic mineral suite that is now volcanic glasses and in the solutions interacting with them. forming in Lake Magadi and that has formed in its Pleistocene pre- Analcime is common in outcrops of the High Magadi and cursors and interprets the reactions responsible for these as- Oloronga Beds. It forms from erionite by a reaction probably ini- semblages in terms of glass chemistry and brine chemistry. We tiated by a lowering of the silica activity, which results from the hope that this approach will result in a better understanding of the transformation of magadiite to chert. Analcime in the drill-core interdependence between authigenic silicates and aqueous samples grew at the expense of a Na-Al-Si gel. This gel forms at the geochemistry. lake shore and is washed into the lake during flooding conditions. Fluorite is common in the core samples and can be explained by STRATIGRAPHY AND LITHOLOGIES reaction of the fluoride-rich brines with calcium in the sediments, principally detrital calcite. Authigenic albite and potassium The Pleistocene and Holocene history of the Magadi basin sedi- feldspar were not recognized, probably for reasons of reaction ments was described in detail by Baker (1958, 1963) and Eugster kinetics. (1969). Lake Magadi is located in the lowest part of the Eastern The presence of authigenic minerals can be accounted for by Rift Valley in Kenya, just north of the Tanzania border. It is mainly considering the chemical compositions of the starting materials, a trona-precipitating saline lake, which is fed by alkaline hot mainly volcanic glasses, and the brines they come in contact with. springs issuing at the perimeter of the basin. The sediments ac- Lake Magadi represents a unique opportunity for studies of cumulating now belong to the Evaporite Series (see Table 1), and diagenesis because authigenic minerals are forming there at the present time and because the evolution of its waters is well known. TABLE 1. STRAT1GRAPHIC UNITS, TECTONIC EVENTS, AND ABSOLUTE AGES OF INTRODUCTION FORMATIONS FOUND IN THE MAGADI BASIN Zeolites are among the most common authigenic silicates of Units Age Lake sedimentary rocks (Hay, 1966). Among the most detailed studies (yr) are those of zeolites from saline alkaline lake environments (see Evaporite Series Sheppard and Gude, 1968, 1969a, 1973; Hay, 1970; Surdam and (slight tilting) 0 Magadi Parker, 1972). These zeolites generally formed by reaction of vol- canic glass with saline alkaline solutions. The alkalic zeolites that High Magadi Beds (minor faulting?) High Magadi result from such reactions are commonly phillipsite, erionite, 9,100 clinoptilolite, and, to a lesser extent, mordenite and chabazite. Trachyte flows (minor) These zeolites may subsequently be transformed to analcime (as in caliche 780,000 the Big Sandy, Barstow, and Green River Formations) or to potas- Oloronga Beds sium feldspar (as in Pleistocene Lake Tecopa). Analcime may also (extensive grid faulting) >780,000 Oloronga react to form potassium feldspar (as in the Big Sandy, Barstow, and Plateau trachyte flows -1,000,000 Green River Formations). (extensive) to 1,700,000 The paragenetic sequence of volcanic glass —» alkalic zeolite —* Note: Data from Eugster (in prep.). analcime —» potassium feldspar is well established. On the other Geological Society of America Bulletin, v. 87, p. 1739-1752, 11 figs., December 1976, Doc. no. 61208. 1739 Downloaded from http://pubs.geoscienceworld.org/gsa/gsabulletin/article-pdf/87/12/1739/3418402/i0016-7606-87-12-1739.pdf by guest on 26 September 2021 1740 SURDAM AND EUGSTER the area of the active lake covers about 60 km2. There is evidence High Magadi and Oloronga Beds are discussed separately. The drill for the existence of two larger precursor lakes in the basin. The cores penetrated a very much thicker section of lake sediments than shoreline of the lake from which the High Magadi Beds were de- is available in the outcrops at the margin of the basin. Exact corre- posited is still visible, and the High Magadi Beds have been dated lation of the stratigraphic units from outcrop to drill core is as 9,100 yr. old (Butzer and others, 1972). The older lake is repre- difficult. Therefore, the drill-core mineralogy is tabulated sepa- sented by the Oloronga Beds, which have been dated by K-A meas- rately from the outcrop mineralogy. A tentative correlation will be urements on a glassy trachyte flow as at least 780,000 yr. old discussed later. (Fairhead and others, 1972; Eugster, in prep.). Below the Oloronga Beds are the extensive plateau trachyte flows that cover the Rift MINERALOGY AND CHEMISTRY OF Valley floor and are as old as 1.7 m.y. (Baker, 1958; Baker and HIGH MAGADI AND OLORONGA BEDS others, 1971). Outcrops of High Magadi and Oloronga Beds occur abundantly High Magadi Beds, Outcrop Samples in the alluvial flats and at the foot of the hills surrounding Lake Magadi (for sample locations, see Fig. 1). The detailed distribution The mineralogy of the High Magadi Beds is characterized by the of the two sets of lake beds is rather complex, because there is a following groups of minerals: (1) detrital silicates, (2) saline miner- considerable region of overlap. However, good Oloronga outcrops als, (3) calcite, (4) sodium silicates and quartz, and (5) authigenic are most common southwest, northwest, and northeast of Lake zeolites. The most abundant detrital silicate is anorthoclase, which Magadi, whereas the High Magadi Beds can best be studied east occurs as fragments of single crystals. These are generally fresh or and southeast of the lake. A detailed account of the stratigraphy, slightly altered to clay minerals and (or) calcite. These fragments lithologies, and sedimentary history will be published elsewhere are identical in mineralogy with the phenocrysts in the trachytic (Eugster, in prep.), and a brief summary will suffice here. lavas and were derived either from pyroclastic ash falls or directly The sedimentary rocks that constitute the High Magadi and from the lavas. Similar anorthoclase fragments are abundant in the Oloronga Beds are very similar; however, the Oloronga Beds are modern muds. Another common detrital mineral is amphibole. The commonly more indurated, and they are capped by a thick caliche amphibole also occurs as crystal fragments, many of which are al- (Kunkar) limestone (50 to 75 cm thick). This caliche is an im- portant stratigraphic marker because it occurs throughout the ba- sin, whereas the post-Oloronga lava flows are restricted to the northwest area (loc. 665 and 696). The sedimentary rocks are prin- LITTLE cipally bedded chert and tuffaceous material. The High Magadi MAGADI cherts have clearly been derived from magadiite horizons (Eugster, 1969), and the Oloronga cherts probably had a similar origin. The tuffaceous material varies greatly. Some tuffs must have formed from pyroclastic debris associated with individual volcanic events. Figure 1. Index and sample-locality map Such tuffs may contain pumice fragments as much as 1 cm in of Lake Magadi region, Kenya, East Africa. diameter. Others also contain detrital material and range from coarse, cross-bedded sandstone to finely laminated mudstone. However, even the clearly detrital components are of volcanic deri- vation. In fact, the sediments of the lower sequence of the High Magadi Beds (Eugster, 1969) may consist principally of eroded Oloronga material. There are no perennial rivers flowing into the Magadi Basin at present, and this condition probably also applied to High Magadi and, perhaps, even Oloronga time. Hence, the sediments in the basin were either derived from within the basin or were carried in by wind. Since the sediments are all underlain by thick sequences of trachytic flows, most of the sediments, except for the cherts, calcite, and organic fractions, are obviously of volcanic origin. EXPLANATION SAMPLING AND SAMPLE LOCATIONS OLORONGA BEDS Samples were obtained from outcrops, shallow pits, and drill HIGH MAGADI BEDS cores.
Load more

Recommended publications
  • Alcolapia Grahami ERSS
    Lake Magadi Tilapia (Alcolapia grahami) Ecological Risk Screening Summary U.S. Fish & Wildlife Service, March 2015 Revised, August 2017, October 2017 Web Version, 8/21/2018 1 Native Range and Status in the United States Native Range From Bayona and Akinyi (2006): “The natural range of this species is restricted to a single location: Lake Magadi [Kenya].” Status in the United States No records of Alcolapia grahami in the wild or in trade in the United States were found. The Florida Fish and Wildlife Conservation Commission has listed the tilapia Alcolapia grahami as a prohibited species. Prohibited nonnative species (FFWCC 2018), “are considered to be dangerous to the ecology and/or the health and welfare of the people of Florida. These species are not allowed to be personally possessed or used for commercial activities.” Means of Introductions in the United States No records of Alcolapia grahami in the United States were found. 1 Remarks From Bayona and Akinyi (2006): “Vulnerable D2 ver 3.1” Various sources use Alcolapia grahami (Eschmeyer et al. 2017) or Oreochromis grahami (ITIS 2017) as the accepted name for this species. Information searches were conducted under both names to ensure completeness of the data gathered. 2 Biology and Ecology Taxonomic Hierarchy and Taxonomic Standing According to Eschmeyer et al. (2017), Alcolapia grahami (Boulenger 1912) is the current valid name for this species. It was originally described as Tilapia grahami; it has also been known as Oreoghromis grahami, and as a synonym, but valid subspecies, of
    [Show full text]
  • Direct Utilization of Geothermal Resources in Kenya
    Proceedings World Geothermal Congress 2010 Bali, Indonesia, 25-29 April 2010 Direct Utilization of Geothermal Resources in Kenya John Lagat Kenya Electricity Generating Company Ltd, P. O. Box 785 Naivasha 20117 E-mail: [email protected] Keywords: Geothermal, direct use, balneology, space 38oE heating, greenhouses, agriculture, aquaculture, industrial North Island processes 4oN L. Turkana ETHIOPIA ABSTRACT Central Island Geothermal resources in Kenya are mainly located along the Kenyan Rift, which is part of the eastern arm of the South Island African Rift. The primary forms of utilization of Cenozoic Barrier Volcano geothermal energy in Kenya currently are mainly electric volcanics power generation (168 MWe) and direct uses (~18 MWt) to UGANDA Namarunu a small extent. Though about 99% of geothermal utilization in the country is generation of electricity, direct uses are Emuruangogolak gaining momentum in various parts of the country. Farmers Mt. Elgon Silali have for decades, used geothermal heat to dry pyrethrum Paka KENYA Korosi flowers and condense steam for drinking at Eburru while L. Baringo Nyambeni the Oserian Development Company in Naivasha is using Arus-Bogoria geothermal energy to heat 50 hectares of greenhouses of cut Kisumu Oo roses for export. A tourist hotel at Lake Bogoria is utilizing Menengai Mt. Kenya spring water at 38°C to heat a spa pool. Despite the Eburru availability and enormous potential in direct use L. Naivasha applications, little use has been made of low enthalpy fluids Olkaria Longonot in Kenya. This paper therefore discusses direct use Suswa applications and available opportunities in swimming, Ol'Esakut Nairobi bathing, balneology, agricultural, aquiculture and in Olorgesaille o residential and industrial sectors L.
    [Show full text]
  • Geology Area South of Magadi
    _£I Report No. 61 GOVERNMENT OF KENYA MINISTRY OF COMMERCE AND INDUSTRY GEOLOGICAL SURVEY OF KENYA GEOLOGY OF THE AREA SOUTH OF MAGADI DEGREE SHEET 58, N.W. QUARTER (with coloured geological map) by B. H. BAKER, B.Sc, F.G.S. Geologist Eight Shillings - 1963 "ISfiICrLIBSARY ïIE-- :i963l4 j». ^itfageningen _ .The'Netherlands Li / J Scanned from original by ISRIC - World Soil Information, as ICSU World Data Centre for Soils. The purpose is to make a safe depository for endangered documents and to make the accrued information available for consultation, following Fair Use Guidelines. Every effort is taken to respect Copyright of the materials within the archives where the identification of the Copyright holder is clear and, where feasible, to contact the originators. For questions please contact soil.isricPwur.nl indicating the item reference number concerned. GEOLOGY OF THE AREA SOUTH OF MAGADI DEGREE SHEET 58, N.W. QUARTER (with coloured geological map) by B. H. BAKER, B.Sc, F.G.S. Geologist 165^G FOREWORD The publication of the report on the geology of the area south of Magadi completes the account of the southern end of the Rift Valley as it occurs in Kenya. The Magadi area itself was described by Mr. Baker in Report No. 42 (1958). During the mapping of the continua­ tion of the Magadi area the discovery of some critical exposures enabled the correction of an error of succession in the lower Pleistocene rocks that had been made during the survey of the Magadi area. The area is wild and desolate, but of considerable interest scenically, with the western Rift wall a little beyond its west boundary, rugged hills of ancient rocks in the south-east and two prominent volcanoes, Lenderut and Shombole, rising from the Rift floor.
    [Show full text]
  • Geothermal Potential of the Kenya Rift
    Presented at Short Course III on Exploration for Geothermal Resources, organized by UNU-GTP and KenGen, at Lake Naivasha, Kenya, October 24 - November 17, 2008. GEOTHERMAL TRAINING PROGRAMME Kenya Electricity Generating Co., Ltd. STATUS OF GEOTHERMAL EXPLORATION IN KENYA AND FUTURE PLANS FOR ITS DEVELOPMENT Peter A. Omenda Kenya Electricity Generating Company Ltd. (KenGen) P.O. Box 785, Naivasha KENYA [email protected] ABSTRACT The high temperature geothermal prospects in Kenya are located within and are associated with the development of the Kenya Rift. Kenya Rift is a continental scale volcano-tectonic feature that stretches from northern to southern Africa. Development of the Rift started during the Oligocene (30million years ago) and activity has continued to recent times. The last 2 million years saw the development of large shield volcanoes within the axis of the rift. These centres are the most important geothermal prospects within the rift. Association between rifting and most of the occurrences of geothermal energy is mainly due to shallow magma chambers underneath the young volcanoes within the rift axis. KenGen in collaboration with the Ministry of Energy of the Government of Kenya has undertaken detailed surface studies of most of the prospects in the central sector of the rift which comprises Suswa, Longonot, Olkaria, Eburru, Menengai, Lakes Bogoria and Baringo, Korosi and Paka volcanic fields. Electric power is currently being generated at Olkaria with 130MWe installed while exploration drilling has been undertaken at Eburru and a 2.5MWe pilot plant is planned for development by KenGen and commissioning by 2009. Common methods that have been used by KenGen during exploration expeditions include geology (lithology, geochronology, structures); geophysics (seismic, gravity, magnetic, and resistivity); geochemistry (fluid and thermometry), heat flow and environmental baseline assessments.
    [Show full text]
  • Geothermal Mapping Using Temperature Measurements
    Presented at Short Course VII on Exploration for Geothermal Resources, organized by UNU-GTP, GDC and KenGen, at Lake Bogoria and Lake Naivasha, Kenya, Oct. 27 – Nov. 18, 2012. GEOTHERMAL TRAINING PROGRAMME Kenya Electricity Generating Co., Ltd. GEOTHERMAL MAPPING USING TEMPERATURE MEASUREMENTS Godwin M. Mwawongo Geothermal Development Company P. O. Box 100746, Nairobi 00101 KENYA [email protected] ABSTRACT Shallow temperature gradient holes are reliable in mapping geothermal prospects with heat loss features as surface manifestation. The sun least affects ground temperatures at 1 m depth and temperatures in the North rift are least affected by seasonal changes. Over 10,736 MWt is lost naturally from Menengai to Paka along the Kenyan rift. Most of the geothermal surface manifestations associated with the heat loss are oriented in the NW-SE with a few located in the NE-SW direction. Estimated down-hole temperature at I km depth is over 200oC. Fluid flow in the prospects from Lake Baringo to Paka is from East to West with an outflow to the north. 1. INTRODUCTION Kenya is located in East Africa where the Great African Rift virtually splits the landmass into two. 14 geothermal prospects have been identified within the Kenyan Rift Valley starting from Barrier in the north to Lake Magadi in the south with a potential of over 3,000 MWe (Figure 1). The rift is a graben and during the formation of the prospects, hot rocks were brought closer to the surface and with intensive faulting and presence of water, the geothermal systems were formed as shown in the model in Figure 2.
    [Show full text]
  • Geology of the Area South of Magadi, Kenya
    %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % %% % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % %% %% % % % % % % %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% % GEOLOGIC HISTORY % % % % % % % % % % % % % % % % % % % Legend % % % % % % % % % % % % % % % % % % % %% % %% %% % HOLOCENE % %% %% %% %% %% % % Pl-na %% %% %% % % Alasho ash %% %% %% % Evaporite Series (0-9 ka): trona with interbedded clays. The Magadi Soda Company currently mines the % % % Sediments Metamorphics %% %% %% %% %% %% %% %% %% %% %% %% % trona at Lake Magadi in the region to the north. Samples of this formation from Natron indicate significantly % %% %% %% %% %% %% %% % % Pl-nv %% % % Alasho centers %% %% %% % G% eology of the Area South of Magadi, Kenya more halite than trona compared to Lake Magadi (Bell and Simonetti 1996). %% % % Holocene Kurase Group %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% %% % % % % % Pl-pt % % % % Magadi Trachyte Xl % % % % PLEISTOCENE % % % % Trona Crystalline Limestone % % % % For area to North see: Geology of the Magadi Area, KGS Report 42; Digital version by A. Guth % % % 36.5 °E % % % % 36.0 °E % % % % % High Magadi Beds (9-23.7 ka): yellow-brown silts over laminated clays with fish remains. Deposited % during % % Pl-gv % -2.0 ° -2.0 ° % % Gelai Xp % %% % a period of higher lake levels in both lakes Natron and Magadi. Coarser pebble beds seen near Len% derut Alluvial fan Undiff. Pelitic
    [Show full text]
  • Status of Geothermal Development
    Proceedings World Geothermal Congress 2010 Bali, Indonesia, 25-29 April 2010 Status of Geothermal Exploration in Kenya and Future Plans for Its Development Silas M. Simiyu Geothermal Development Company Ltd, P. O. Box 100746-00101 Nairobi, Kenya [email protected] Keywords: Geothermal, Kenya rift, Country update, equivalent over the 20 year period requires drilling about Potential 1,000 deep wells, using 10 rigs at a total cost of about US$ 5 Billion. 30 Power stations (about 140 MW each) would ABSTRACT be required at a total cost of about US$ 8 Billion; steam Kenya is endowed with vast geothermal resource potential gathering systems at about US$ 1 Billion; and power along the world Kenya Rift that transects the country from transmission lines at about US$ 2 Billion. It is clear that north to south. Exploration reveals that geothermal potential such a massive (US$ 16 Billion) capital intensive exceeds 7,000 MWe and is capable of meeting all of undertaking can only be realized through a joint effort by Kenya’s electricity needs over the next 20 years. Out of this both the public and private sectors. potential, only 167 MWe and 18 MWt are being utilized for indirect and direct uses respectively. Kenya Electricity 1.1 Regional Geologic Tectonic Setting Generating Company Ltd (KenGen) and Geothermal The Kenya rift valley (Figure 1) is part of the African rift Development Company Ltd (GDC) in collaboration with system that runs from Afar triple junction in the north to the Ministry of Energy (MoE) has undertaken detailed Beira, Mozambique in the south.
    [Show full text]
  • Geology of the Magadi Area, Kenya %
    % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % % %% % % % % % % % % % % % % % % % % % % % % % % % % %% % % % % % % % % % % %% % % % % % % % % % % % % % % % % % %% % % % % % % % % % % % % % % % % % % % % % % % % % % % % GEOLOGIC HISTORY % % % % % % % % % % % % % % % % % % % % % % % Legend % % % % % % % % % % % % % % % % %% % % % % % % % % % % % % % % % % % % % % % % % % HOLOCENE % % % % % % % % % Pleistocene Pleistocene: Gelasian % % % % % % % % %% %% %% % % % % %% % % Sediments % % % % %% % Evaporite Series (0-9 ka): trona with interbedded clays. The Magadi Soda Company at Lake Magadi % % % % %% %% % % % % % % % % % % % % % % % % % % % % % Pl-cv % currently mines the trona. % % Cinder cones Pl-let Leshuta Trachyte % % % % % % % % % % % % % % % % % % % % Holocene % % % % % Geology of the Magadi Area, Kenya % %% % % % % % % % % % % % % % % %% % %% % % %% % % % % % % % % % % PLEISTOCENE % % % Pl-kjb Kordjya Basalt % % % % % % % % % % % Nyokie % % %% % Trona % % % % % % % % % % % % High Magadi Beds (9-23.7 ka): yellow-brown silts over laminated clays with fish remains. Deposited during % % % % % % % % % % For area to North see: Geology of the Suswa Area, KGS Report 97; Digital version by A. Guth % % % % 36.5 °E % % % 36.0 °E % % % % % % % % % % % a period of higher lake levels in both lakes Natron and Magadi. % % % Pl-mt % % % % Mosiro Trachyte satellite lava % % % % % -1.5 ° % % % % % -1.5
    [Show full text]
  • Lake Nakuru Flamingoes
    www.saltworkconsultants.com Salty MattersJohn Warren - Friday, May 23, 2016 Lake Nakuru flamingoes– Life’s response to feast and famine in schizohaline lacus- trine hydrologies The Flamingo Connection Nakuru, leaving enough pink carcases to spur an interna- tional newspaper to describe the lake as a “flamingo death An aviator once described Lake Nakuru as “a crucible of camp.” Two years prior, 43,800 of the birds had perished pink and crimson fire,” with a million flamingos painting at Tanzania’s Lake Manyara, the first major die-off docu- an astonishing band of colour that burst into pieces as the mented at that alkaline, soda-rich lake. Previous mass die- birds took flight (Figure 1). offs occurred at Lake Nakuru and two other Kenyan lakes Flamingo population levels in Lake Nakuru and any mass in 1993, 1995, and 1997, as well as at two lakes in Tanzania “die-offs” are popularly considered as indicators of the en- in 2002. At the same time, birds were gathering in places vironmental health of Nakuru and other lakes in the Af- they have never been documented before. Since 2006 there rican rift valley with significant flamingo populations. In have been additional population crashes at Nakuru and El- 2006, more than 30,000 of the birds were found dead at mentia (Table 1). Figure 1. Flamingo ock feeding on the edge of Lake Nakuru (full-size image can be downloaded from http://www.yannarthusber- trand2.org) Page 1 www.saltworkconsultants.com Date of crash Lake Reference where these birds dominate the macrofauna in 1971 Elmenteita Melack and Kilham 1974 some modern saline lakes, are described by Scott 1973 Nakuru Vareschi et al.
    [Show full text]
  • Geothermal Development in Kenya: a Country Update - 2012
    Geothermal Development in Kenya: A Country Update - 2012 Peter A. Omenda Geothermal Development Company Ltd, P. O. Box 100746-00101 Nairobi, Kenya [email protected] Keywords: Geothermal, Kenya rift, Country update, 1.1 Electricity Subsector Potential Electricity remains the most sought after energy source by the Kenyan society and access to it is normally associated ABSTRACT with rising, or high quality of life. However, its consumption Kenya is endowed with vast geothermal resource potential in Kenya is extremely low at 121 kilowatt hours (KWh) per along the world Kenya Rift that transects the country from capita (compared to 503 KWh in Vietnam or 4,595 KWh for north to south. Exploration reveals that geothermal potential South Africa). About 29% of Kenyans are connected to exceeds 10,000 MWe. Out of this potential, only 212.5 electricity while the connection rate in the rural areas is MWe and 18 MWt are being utilized for indirect and direct estimated at 15%. This situation is rapidly changing as the uses, respectively. Kenya Electricity Generating Company country invests more resources in power generation, Ltd (KenGen) and Geothermal Development Company Ltd transmission and distribution. In addition, policy and (GDC) have undertaken detailed surface studies of most of institutional reforms in the sector are being implemented to the prospects in the Kenya rift and active drilling is in create room for new providers. progress in the Greater Olkaria field and at Menengai. The Least Cost Power Development Plan (2010-2030) prepared 1.2 Institutional Structure in Kenya by the Government of Kenya indicates that geothermal Following the enactment of the Energy Act No.
    [Show full text]
  • Chronostratigraphic Model of a High-Resolution Drill Core Record Of
    Quaternary Science Reviews 215 (2019) 213e231 Contents lists available at ScienceDirect Quaternary Science Reviews journal homepage: www.elsevier.com/locate/quascirev Chronostratigraphic model of a high-resolution drill core record of the past million years from the Koora Basin, south Kenya Rift: Overcoming the difficulties of variable sedimentation rate and hiatuses A.L. Deino a, *, R. Dommain b, c, C.B. Keller a, d, R. Potts b, A.K. Behrensmeyer e, E.J. Beverly f, J. King g, C.W. Heil g, M. Stockhecke h, E.T. Brown h, J. Moerman b, P. deMenocal i, j, the Olorgesailie Drilling Project Scientific Team1 a Berkeley Geochronology Center, 2455 Ridge Road, Berkeley, CA 94709, USA b Human Origins Program, National Museum of Natural History, Smithsonian Institution, Washington, DC 20013-7012, USA c Institute of Geosciences, University of Potsdam, Karl-Liebknecht-Straße 24-25, 14476 Potsdam-Golm, Germany d Department of Earth Sciences, Dartmouth College, Hanover, NH 03755, USA e Department of Paleobiology, National Museum of Natural History, Smithsonian Institution, Washington, DC 20013-7012, USA f University of Houston, Department of Earth and Atmospheric Sciences, Science & Research Building 1, 3507 Cullen Blvd, Rm. 312, Houston, TX 77204-5007, USA g Graduate School of Oceanography, University of Rhode Island, South Ferry Road, Narragansett, RI 02882, USA h Large Lakes Observatory, University of Minnesota Duluth, Duluth, MN 55812, USA i Department of Earth and Environmental Sciences, Columbia University, Palisades, NY 10964, USA j Lamont-Doherty Earth Observatory, Columbia University, Palisades, NY 10964, USA article info abstract Article history: The Olorgesailie Drilling Project and the related Hominin Sites and Paleolakes Drilling Project in East Received 27 February 2019 Africa were initiated to test hypotheses and models linking environmental change to hominin evolution Received in revised form by drilling lake basin sediments adjacent to important archeological and paleoanthropological sites.
    [Show full text]
  • Diversity and Distribution of Fungal Communities Within the Hot Springs of Soda Lakes in the Kenyan Rift Valley
    Vol. 11(19), pp. 764-775, 21 May, 2017 DOI: 10.5897/AJMR2017.8510 Article Number: 7B86FFB64447 ISSN 1996-0808 African Journal of Microbiology Research Copyright © 2017 Author(s) retain the copyright of this article http://www.academicjournals.org/AJMR Full Length Research Paper Diversity and distribution of fungal communities within the hot springs of soda lakes in the Kenyan rift valley Odilia Atamba Salano1*, Huxley Mae Makonde2, Remmy Wekesa Kasili1, Laura Nyawira Wangai3, Mildred Pauline Nawiri4 and Hamadi Iddi Boga5 1Institute for Biotechnology Research, Jomo Kenyatta University of Agriculture and Technology, P. O. Box 62000 - 00200, Nairobi, Kenya. 2Department of Pure and Applied Sciences, Technical University of Mombasa, P. O. Box 90420 - 80100, GPO, Mombasa, Kenya. 3School of Health Sciences, Kirinyaga University, P. O. Box, 143-10300, Kerugoya, Kenya. 4Department of Chemistry, Kenyatta University, P. O. Box, 43844-00100, Nairobi, Kenya. 5Taita Taveta University, School of Agriculture, Earth and Environmental Sciences, P.O. Box 635-80300, Voi, Kenya. Received 6 March, 2017; Accepted 20 April, 2017 Fungi are highly diverse and versatile, with members growing under different environmental conditions including extreme environments. Although fungal communities in some extreme environments have been investigated in recent years, little is known about their structure and richness within the hot springs of soda lakes in Kenya. The aim of the study was to determine the biogeography and diversity of fungi from the hot springs of four Soda lakes. Water, sediment and microbial mat samples were collected in triplicates from Lakes Bogoria, Magadi, Elmenteita and Little Magadi in Kenya. 454- Pyrosequencing was used to sequence amplicons of Internal Transcribed Spacer (ITS) gene region of the total community DNA in order to explore the fungal community composition in twenty four samples collected.
    [Show full text]