Effect of Electrode Material and Hydrodynamics on the Produced Current in Double Chamber Microbial Fuel Cells.

Abstract

In recent decades, there has been huge interest in exploring cost-effective and sustainable ways for energy production using fuel cells. In this study, different electrode materials, namely, nickel, stainless steel, brass, and graphite were used to investigate the energy production in double chamber microbial fuel cells. Yeast microorganisms (MOs) (Saccharomyces cerevisiae) were used at different concentrations for electricity production under different operating conditions with glucose as a substrate. The produced current and potential of the electrode were measured for ranges of operating conditions such as MO concentration (1–8 g/L), flow velocity (0–600 rpm), and aeration of the catholyte. It was found that there was a different performance exhibited by each electrode material, with nickel and graphite giving the highest efficiency. Increasing the flow velocity and aeration in the cathode compartment led to increasing the produced current while the flow and aeration in the anode compartment had a negative effect on the produced current. Simultaneous aeration and agitation gave high produced current values, while high agitation with aeration reduced the efficacy. The increased concentration of substrate glucose showed different influences on the produced current depending on electrode materials.