Sulfate and organic carbon removal by microbial fuel cell with sulfate-reducing bacteria and sulfide-oxidising bacteria anodic biofilm
Journal
Bioresource Technology
Journal Volume
156
Pages
14-19
Date Issued
2014
Author(s)
Abstract
Biological sulfur removal can be achieved by reducing sulfate to sulfide with sulfate-reducing bacteria (SRB) and then oxidising sulfide to elemental sulfur (S0) with sulfide oxidising bacteria (SOB) for recovery. In sulfate-carbon wastewaters lacking electron acceptor for sulfide, excess sulfide will be produced and accumulated in the reactor. This study applied the microbial fuel cell (MFC) cultivated with the SRB+SOB anodic biofilm for treating the sulfate+organic carbon wastewaters. Excess sulfate ions were efficiently converted to sulfide by SRB cells in the biofilm, while the formed sulfide was diffused to the neighboring SOB cells to be irreversibly converted to S0 with produced electrons being transferred to the anode. The cell-cell sulfide transport principally determined the electron flux of the MFC. Short diffusional distance of sulfide ions between cells significantly reduced the polarization resistances, hence enhancing performance of the MFC. © 2014 Elsevier Ltd.
Subjects
Diffusion; Microbial fuel cell; Sulfate; Sulfide
SDGs
Other Subjects
Bacteria; Biofilms; Cells; Cytology; Diffusion; Microbial fuel cells; Wastewater treatment; Anodic biofilms; Electron acceptor; Elemental sulfur; Organic carbon removals; Polarization resistances; Sulfate; Sulfate reducing bacteria; Sulfide; Sulfur compounds; lactic acid; organic carbon; sulfate; sulfide; carbon; organic compound; sulfate; sulfide; bacterium; biofilm; biotechnology; diffusion; electrode; fuel cell; microbial activity; organic carbon; performance assessment; pollutant removal; reduction; sulfate; sulfide; waste treatment; wastewater; activated sludge; article; biofilm; cation exchange; cell transport; cyclic potentiometry; desulfurization; diffusion; electrochemical analysis; electrochemical impedance spectroscopy; electrode; electron; electron transport; microbial fuel cell; nonhuman; pH measurement; polarization; power supply; priority journal; sulfate reducing bacterium; sulfide oxidizing bacterium; waste component removal; waste water management; Bacteria; bioenergy; bioremediation; electricity; isolation and purification; metabolism; oxidation reduction reaction; time; Bacteria; Biodegradation, Environmental; Bioelectric Energy Sources; Biofilms; Carbon; Dielectric Spectroscopy; Electricity; Electrochemical Techniques; Electrodes; Organic Chemicals; Oxidation-Reduction; Sulfates; Sulfides; Time Factors
Type
journal article