TY - JOUR
T1 - The Use of Algal Biomass to Sustain Sulfidogenic Bioreactors for Remediating Acidic Metal-Rich Waste Waters
AU - Santos, Ana Laura
AU - Johnson, D. Barrie
PY - 2017
Y1 - 2017
N2 - Two different species of acidophilic micro-algae were grown in axenic culture, biomass harvested and injected into a low pH sulfate-reducing bioreactor, to act as a substrate for biosulfidogenesis. The hydrogen sulfide generated was used to precipitate copper in an off-line vessel, and the bioreactor pH was maintained by automated addition of a pH 2.5 feed liquor, to compensate for protons consumed by biosulfidogenesis. Results demonstrated the potential for using algal biomass for this purpose, precipitating about 1.5 mg Cu2+ L-1h-1, though rates of sulfidogenesis were considerably slower that when glycerol and yeast extract were used as organic feed-stocks.
AB - Two different species of acidophilic micro-algae were grown in axenic culture, biomass harvested and injected into a low pH sulfate-reducing bioreactor, to act as a substrate for biosulfidogenesis. The hydrogen sulfide generated was used to precipitate copper in an off-line vessel, and the bioreactor pH was maintained by automated addition of a pH 2.5 feed liquor, to compensate for protons consumed by biosulfidogenesis. Results demonstrated the potential for using algal biomass for this purpose, precipitating about 1.5 mg Cu2+ L-1h-1, though rates of sulfidogenesis were considerably slower that when glycerol and yeast extract were used as organic feed-stocks.
UR - https://www.scientific.net/SSP.262.577
M3 - Article
SN - 1662-9779
VL - 262
SP - 577
EP - 581
JO - Solid State Phenomena
JF - Solid State Phenomena
ER -