Cladophora sp. Biosorption of Metal-contaminated Water

Abstract

Artisanal and Small-scale Gold Mining (ASGM) activities employing the mercury amal-gamationtechnique have resulted in a significant drop in the quality of water from Ngwabalozi River, Zimbabwe. Mercury levels as high as 0.31 mg L-1have been reported in its waters and the low river pH (pH 3) favors proliferation of microorganisms responsible for methylmercury (a potent neurotoxin) formation. Thus, removal of mercury from contaminated systems is a priority. Therefore, the aim of this study is to develop a low-cost batch reactor for the removal of mercury from mercury contaminated acidic waters tomeet the World Health Organization (WHO) standard of 0.006 mg L-1using Cladophorasp. algae. Optimum reactor parameters were deter-mined by studying the effect of contact time, pH, initial mercury concentration and the presence of competing cations on the adsorption of mercury by Cladophorasp. The mass of algae required in a 1000 Lbatch reactor was then determined at the optimum adsorption conditions for the single and multi-component solution systems. A rapid uptake of mercury by Cladophorasp. algae was displayed. More than 99% of the mercury in solution was removed within the first five minutes of contact and equilibrium was attained after ten minutes. High adsorption capacities (up to 805 mg kg-1at pH 3) were obtained at the optimum mercury concentration of 1.0 mg L-1. Competitive adsorption studies showed that the selectivity of cations by Cladophora sp. was in thefollowing order: Hg2+˃ Fe2+˃ Cu2+˃ Zn2+˃ Co2+. Based on the optimized reactor conditions, nearly 4.8 kg of Cladophorasp. per 1000 Lbatch is required to treat the water in Ngwabalozi River for a mercury only solution. However, for a multi-component system, the mass of Cladophorasp. required was more than triple (17.1 kg) the mass required in a single component solution.