Abstract
Microbial fuel cells (MFCs) that simultaneously remove organic contaminants and recovering metals provide a potential route for industry to adopt clean technologies. In this work, two goals were set: to study the feasibility of zinc removal from industrial effluents using MFCs and to understand the removal process by using reaction rate models. The removal of Zn2+ in MFC was over 96% for synthetic and industrial samples with initial Zn2+ concentrations less than 2.0 mM after 22 h of operation. However, only 83 and 42% of the zinc recovered from synthetic and industrial samples, respectively, was attached on the cathode surface of the MFCs. The results marked the domination of electroprecipitation rather than the electrodeposition process in the industrial samples. Energy dispersive X-ray (EDX) analysis showed that the recovered compound contained not only Zn but also O, evidence that Zn(OH)2 could be formed. The removal of Zn2+ in the MFC followed a mechanism where oxygen was reduced to hydroxide before reacting with Zn2+. Nernst equations and rate law expressions were derived to understand the mechanism and used to estimate the Zn2+ concentration and removal efficiency. The zero-, first- and second-order rate equations successfully fitted the data, predicted the final Zn2+ removal efficiency, and suggested that possible mechanistic reactions occurred in the electrolysis cell (direct reduction), MFC (O2 reduction), and control (chemisorption) modes. The half-life, t1/2, of the Zn2+ removal reaction using synthetic and industrial samples was estimated to be 7.0 and 2.7 h, respectively. The t1/2 values of the controls (without the power input from the MFC bioanode) were much slower and were recorded as 21.5 and 7.3 h for synthetic and industrial samples, respectively. The study suggests that MFCs can act as a sustainable and environmentally friendly technology for heavy metal removal without electrical energy input or the addition of chemicals.
Highlights
Zinc has a variety of applications, such as in corrosion-resistant coatings, dry-cell batteries, alloys, paints, plastics, rubber, dyes, wood preservatives and cosmetics
The study demonstrated the feasibility of microbial fuel cells (MFCs) for the removal of Zn from actual industrial wastewaters without the assistance of an external energy supply
The zinc recovery in terms of Zn(OH)2 accumulation on the cathode surface was 83 and 42% for the synthetic and industrial samples, respectively, while the rest of the zinc precipitate was found in the remaining catholyte
Summary
Zinc has a variety of applications, such as in corrosion-resistant coatings, dry-cell batteries, alloys, paints, plastics, rubber, dyes, wood preservatives and cosmetics. Several treatment methods have been used to remove heavy metals from wastewater streams Most of these methods, such as chemical precipitation and coagulationflocculation, are only reliable when treating high concentrations of heavy metals (e.g., >1000 ppm) and require the usage of chemical reagents. These methods increase the cost of operation and the complexity of the treatment of wastewaters, as secondary byproducts are generated during the treatment and require further disposal (Fu and Wang, 2011). An effective but low-cost method is necessary for treating wastewaters containing medium to low concentrations of metals
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