Results

Sediment characterization by size and density fraction revealed that the heavier density (>1.8 s.g.) mineral fraction of the sediment comprising sand/silt/clays contributed to 94% of the sediment mass but only 32% of the total PCBs and 11% of the total PAHs. In comparison, the lighter density organic fraction comprising coal/charcoal/coke/wood comprised only 6% of the sediment mass but contained 68% of the PCBs and 89% of the PAHs.

Results from three biological and three physicochemical tests showed that PCB availability was reduced significantly when contaminated sediments were treated with activated carbon and mixed for 1 month. Aqueous equilibrium PCB concentrations were reduced by 86% for activated carbon-treated sediment relative to untreated. Total PCBs released to semi-permeable membrane devices decreased by 72% for activated carbon-treated sediment. Treating sediment with activated carbon reduced PCB bioaccumulation by 69% in Macoma balthica (clam). The percent reduction in PCB uptake varied with PCB chlorination level and ranged from 83% for the pentachlorobiphenyls to 47% for the octachlorobiphenyls. The parallel test with coke amendment showed that the addition of coke had no significant impact on PCB bioaccumulation. Similar reductions in PCB bioaccumulation with activated carbon were observed in two other benthic organisms: 83% in Neanthes arenaceodentata (worm) and 72% in Leptocheirusplumulosus (amphipod).

The effect of dose on reducing the chemical availability of PCBs and PAHs and the bioavailability of PCBs was tested by contacting sediment with activated carbon at concentrations of 0.34%, 1.7%, and 3.4%, dry mass basis. Results showed that increasing carbon dose increased the effectiveness of carbon treatment. Adding 3.4% carbon was more effective than adding 1.7%, thus showing that the optimal dose has likely not been reached. A separate experiment using activated carbon crushed to smaller size (< 75μm) showed that smaller particle diameter activated carbon was significantly more effective (98% reduction) at reducing aqueous equilibrium concentrations than uncrushed (75–300 μm) (92% reduction).

Coke decreased PAH aqueous equilibrium concentrations by 38-64%, depending on coke dose and particle size. Adding coke had a negligible effect on reducing PCB bioaccumulation in benthic organisms, probably due to slow kinetics of PCB diffusion into the particles. The greater effectiveness of activated carbon compared to coke is attributed to a much greater available surface area and internal porosity and the ability to bind organic contaminants such as PCBs and PAHs. Results from the physicochemical tests suggested that adding activated carbon to contaminated field sediment reduces HOC availability to the aqueous phase. The benefit is manifested relatively quickly under optimum contact conditions and improves in effectiveness with contact time.