Rhizosphere properties and heavy metal accumulation of plants growing in the fly ash dumpsite, Morupule power plant, Botswana

Katumelo Gajaje; Venecio U Ultra Jr; Pearl Wathuto David; Gaolathe Rantong

doi:10.1007/s11356-020-11905-7

Rhizosphere properties and heavy metal accumulation of plants growing in the fly ash dumpsite, Morupule power plant, Botswana

Environ Sci Pollut Res Int. 2021 Apr;28(16):20637-20649. doi: 10.1007/s11356-020-11905-7. Epub 2021 Jan 6.

Authors

Katumelo Gajaje¹, Venecio U Ultra Jr², Pearl Wathuto David¹, Gaolathe Rantong³

Affiliations

¹ Department of Earth and Environmental Science, Botswana International University of Science and Technology, Palapye, Botswana.
² Department of Earth and Environmental Science, Botswana International University of Science and Technology, Palapye, Botswana. ultrav@biust.ac.bw.
³ Department of Biology and Biotechnology, Faculty of Science, Botswana International University of Science and Technology, Palapye, Botswana.

PMID: 33405121
DOI: 10.1007/s11356-020-11905-7

Abstract

Discarding fly ash from a coal power plant into a dumpsite does not only contribute to deforestation and loss of productive land but also leads to contamination of air, soil, and groundwater. Therefore, fly ash should be managed properly to avoid the migration of contaminants. One management option is phytoremediation using adapted plants and as a prerequisite, there is a need to identify suitable plants that can be used for revegetation of fly ash dumpsites. To identify prospective plants, a survey was carried out by assessing the plants growing in Morupule B fly ash dumpsite based on their ability to accumulate heavy metals and their bioconcentration (BAF) and translocation factors (TF). Of the twenty-two-plant species growing in the fly ash dumpsite of Morupule B power plant station, N. glauca is a potential phytoextraction agent for Cu (TF_Cu = 1.02; BAF_Cu = 2.16) and Pb (TF_Pb = 1.38; BAF_Pb = 1.65); P. burchellii for Pb (TF_Pb = 1.61, BAF_Pb = 0.9) and Zn (TF_Zn = 1.35; BAF_Zn = 5.74); I. pes-tigridis for Pb (TF_Pb = 1.35; BAF_Pb = 1.56) and Zn (TF_Zn = 1.62; BAF_Zn = 7.43); A. pungens for Cr (TF_Cr = 1.22; BAF_Cr = 0.11), Cu (TF_Cu = 2.18; BAF_Cu = 1.14), and Zn (TF_Zn = 1.04; BAF_Zn = 1.44); E. hirta for Zn (TF_Zn = 1.54, BAF_Zn = 2.44); A. spinosus for Pb (TF_Pb = 1.29; BAF_Pb = 1.55); C. dactylon for Cu (TF_Cu = 1.86; BAF_Cu = 1.07) and Zn (TF_Zn = 1.00; BAF_Zn = 2.46); and D. aegyptium for Pb (TF_Pb = 1.19; BAF_Pb = 2.57). Other plants growing in the fly ash dumpsite are potential candidates for phytostabilization as they can tolerate a high concentration of metals and low essential nutrients. Also, different plant groups variably modified the pH, EC, OM, and exchangeable fractions of metals in the rhizosphere wherein grasses can increase the OM at higher rates, and it has a higher capacity to acidify and solubilize heavy metals in the rhizosphere leading to higher EC and available metals compared to other plant groups. Overall, the information presented is useful in identifying plants or their combinations for the phytoremediation of fly ash and other heavy metal-polluted environments.

Keywords: Bioaccumulation; Fly ash dumpsite rehabilitation; Metal accumulation; Phytoremediation.

MeSH terms

Biodegradation, Environmental
Botswana
Coal Ash
Metals, Heavy* / analysis
Power Plants
Rhizosphere
Soil Pollutants* / analysis

Substances

Coal Ash
Metals, Heavy
Soil Pollutants

Abstract

MeSH terms

Substances

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