Abstract
This study investigates the impacts of bismuth and tin on the production of CH(4) and volatile fatty acids in a microbial electrosynthesis cell with a continuous CO(2) supply. First, the impact of several transition metal ions (Ni(2+), Fe(2+), Cu(2+), Sn(2+), Mn(2+), MoO(4)(2-), and Bi(3+)) on hydrogenotrophic and acetoclastic methanogenic microbial activity was evaluated in a series of batch bottle tests incubated with anaerobic sludge and a pre-defined concentration of dissolved transition metals. While Cu is considered a promising catalyst for the electrocatalytic conversion of CO(2) to short chain fatty acids such as acetate, its presence as a Cu(2+) ion was demonstrated to significantly inhibit the microbial production of CH(4) and acetate. At the same time, CH(4) production increased in the presence of Bi(3+) (0.1 g L(-1)) and remained unchanged at the same concentration of Sn(2+). Since Sn is of interest due to its catalytic properties in the electrochemical CO(2) conversion, Bi and Sn were added to the cathode compartment of a laboratory-scale microbial electrosynthesis cell (MESC) to achieve an initial concentration of 0.1 g L(-1). While an initial increase in CH(4) (and acetate for Sn(2+)) production was observed after the first injection of the metal ions, after the second injection, CH(4) production declined. Acetate accumulation was indicative of the reduced activity of acetoclastic methanogens, likely due to the high partial pressure of H(2). The modification of a carbon-felt electrode by the electrodeposition of Sn metal on its surface prior to cathode inoculation with anaerobic sludge showed a doubling of CH(4) production in the MESC and a lower concentration of acetate, while the electrodeposition of Bi resulted in a decreased CH(4) production.