3.3. Bioremediation of metals in th

3.3. Bioremediation of metals in the contaminated soil

The fractions of metals remediated (%) by varying ratios of compost and soil mixtures are shown in Fig. 2. A similar trend of metal removal was observed in the two treatments i.e., bioremediation with ‘compost-only’ and ‘compost + plant’. The remediation ability of the treatment with compost and plant effectively removed greater percentage of metals than the ‘compost-only’ treatment. In ‘compost + plant’ treatment, higher fractions of Mn (31%), Fe (49%), Cu (51%) and Zn (31%) were removed than in ‘compost-only’ treatment. An exception is that, Cr showed a higher removal rate (64%) in ‘compost-only’ treated soil than in ‘compost + plant’ treatment.
Treatments with 1:1 compost/soil mixtures were able to remove the highest fractions of metals while treatments with 1:5 ratios removed the least amount of metals. This may be attributed to high organic matter content present in the 1:1 compost/soil mixtures, which have the highest compost concentration compared to other treatments. Mn was the highest remediated metal followed by Fe and Zn while Cr was the least remediated metal.

On the average, during the one month of bioremediation experiment; treatments with ‘compost-only’ removed from the contaminated soil 49 ± 8% Mn, 32 ± 7% Fe, 29 ± 11% Zn, 27 ± 6% Cu and 11 ± 5% Cr. The treatments with ‘compost + plant’ remediated 71 ± 8% Mn, 63 ± 3% Fe, 59 ± 11% Zn, 40 ± 6% Cu and 5 ± 4% Cr. The fraction of Cr removed in this study was lower than the percent Cr remediated in the Cr-eluted soil reported by Mangkoedihardjo et al. [17]. Using columns of sands amended with different levels of composts, Morgan et al. [53] found that 90% of metals (Cd, Cu and Zn) were removed from synthetic stormwater in the outflow of bioretention systems.