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Author
Mwirigi, P.Rutagemwa, D.
Gikuma-Njuru, P.
Njuguna, H.
Matovu, A.
Waya, R.
Mwebaza-Ndawula, L.
Ssenfuma-Nsubuga, M.
Kinobe, J.
Abuodha, J.
Hecky, R.
Date
2005
Metadata
Show full item recordAbstract
Water quality monitoring activities were carried out on physical-chemical parameters, water chemistry and biotic indices at selected littoral and pelagic stations along north-south and east-west transects over an annual cycle between 2000 and 2005. The activities were aimed at collecting baseline information and data for use to define the current lake conditions and make a water quality assessment of the lake in relation to nutrient/ pollutant loadings as a basis for future monitoring surveys. As much as possible current conditions of the lake were compared to past observations where field sites coincided with those of historical studies. Littoral stations (0-20m) showed higher temperatures, pH, turbidities and electrical conductivity while Secchi depths and dissolved oxygen were lower compared to pelagic ones. Deeper pelagic sites experience thermal stratification, leading to strong differences between surface and deep water layers especially in terms of temperature and dissolved oxygen except for June through August during which the lake achieves complete mixing in all stations. On average, littoral stations have higher total nitrogen, chlorophyll, organic matter as well as total particulate carbon. Phytoplankton production and biomass in shallow inshore sites is light-limited due to self shading and the latter can therefore sustain higher algal biomasses because of limited mixing depths. Nitrogen often limits algal growth except for Cyanobacteria that can fix atmospheric nitrogen to meet their N limitations. The higher algal biomass accounts for the higher TN concentrations, chlorophyll and organic matter at littoral sites. During thermal stratification, TP and SRP concentrations are comparable in littoral and pelagic sites while during and just after mixing, both fractions of P are higher in the littoral areas. Continuous excess SRP and the ability of Cyanobacteria to fix atmospheric nitrogen create nutrient saturated conditions that result in light limitation for algal growth. Annual rainfall is characterised by two peaks in the stratification seasons 2 and 3 and appears to be the main source of nutrient enrichment in the lake, particularly TP. Decomposition of organic matter during the stratification period results into release of TP and Si into deeper waters where they build up to much greater concentration than in surface waters. TN reaches annual minimum during the deep mixing period because of N-poor deep waters. Chlorophyll concentrations also reach their annual minimum at this time as deep mixing imposes strong light limitation on algal growth and nitrogen fixation especially in pelagic areas. Comparisons with historical records show that the lake today is warmer than in the 1960s but with lower oxygen and pH in the deeper waters. Thus deep water respiration rates, oxygen consumption and CO2 are higher in the 2000s largely attributed to the eutrophication of the lake. Oxygen depletion in deeper waters during thermal stratification has led to loss of habitat for fish and other biota. Chlorophyll levels, phosphorus concentrations and electrical conductivity in both littoral and pelagic stations have increased compared to records of the 1960s. On the other hand nitrogen concentrations around marginal bays and gulfs have not shown a marked increase compared to historical records of the 1960s and 1970s. Dissolved silicon in the pelagic areas has decreased 5-20 times compared to historical records as eutrophication has increased Si demand by diatoms relative to rather constant supply from the catchment. In line with increased algal turbidities, Secchi depths have decreased at least two-fold since the 1960s. The need for lake wide regular water quality surveys and basin developments in support of appropriate management interventions can not be overemphasized at present in order to determine whether the lake is continuing along the same trends over time documented in this report.Page Range
pp.62-80Title of Parent Book or Report
Lake Victoria Environment Management Project (LVEMP) Water Quality and Ecosystem Status: Lake Victoria Regional Water Quality Synthesis Report.Publisher or University
Lake Victoria Environment Management Project (LVEMP)Collections