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http://dx.doi.org/10.5141/ecoenv.2014.006

Phytoremediation potential of indigenous Ghanaian grass and grass-like species grown on used motor oil contaminated soils  

Akutam, Abednego (Department of Botany, University of Ghana)
Pappoe, Alexander Nii Moi (Department of Environmental Science, University of Cape Coast)
Armah, Frederick Ato (Environmental Health and Hazards Lab, Department of Geography, Western University)
Enu-Kwesi, Lewis (Department of Botany, University of Ghana)
Publication Information
Journal of Ecology and Environment / v.37, no.2, 2014 , pp. 41-51 More about this Journal
Abstract
This study investigated the ability of Bothriochloa bladhii (Retz.) S.T. Blake (Poaceae), Cyperus ligularis L. (Cyperaceae), Commelina erecta L. (Commelinaceae), Mariscus umbellatus (Rottb.) Vahl (Cyperaceae), Fimbistylis miliacea L. (Cyperaceae) and Torulinium odoratum L. (Cyperaceae) to clean up various levels of used motor oil (UMO) contaminated soils. The plants were grown in 2 kg garden soils treated to 0%, 1%, 5% and 10% levels of UMO contamination. The plant growth parameters, chlorophyll contents and dry weight of test plants were measured. The phytoremediation ability of these test plants were assessed by measuring the uptake of hydrocarbons in terms of total hydrocarbon content (THC) as well as their percentage degradation values. There was significant (P < 0.05) reduction in leaf chlorophyll contents and dry weights of the test plant species planted in UMO contaminated soils. THC as well as the percentage uptake (or degradation) of hydrocarbons were both lowest in C. ligularis but highest in T. odoratum in all cases. The phytoremediation potential of test plants was highest in soils contaminated with 5% UMO. Based on the results of this study, all test plants with the exception of C. ligularis were potentially capable of undertaking phytoremediation. However, B. bladhii and T. odoratum proved most effective in the uptake and degradation of UMO.
Keywords
Bothriochloa bladhii; contamination; motor oil; organic; phytoremediation; Torulinium odoratum;
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