A high performance membraneless microfluidic microbial fuel cell for stable, long-term benchtop operation under strong flow.

Strong control over experimental conditions in microfluidic channels provides a unique opportunity to study and optimize membraneless microbial fuel cells (MFCs), particularly with respect to the role of flow. However, improved performance and transferability of results to the wider MFC community require improvements to device stability under all applied operational conditions. To address these challenges, we present an easy-to-fabricate membraneless MFC that combines (i) O2 elimination via a gas diffusion barrier, (ii) integrated graphite electrodes, and (iii) optimized electrode placement to avoid of cross-contamination under all applied flow rates. Attention to all of these design features in the same platform resulted in operation of a MFC with a pure-culture anaerobic Geobacter sulfurreducens biofilm for half a year, six times longer than previously reported, without the use of an oxygen scavenger. As a result of higher device stability under high flow rates, power densities were four times higher than reported previously for microfluidic MFCs with the same biofilm.