High-rate Biohydrogen Production in Single-Chamber Microbial Electrolysis Cell Using Iron-Sulfide Modified Biocathode

Microbial electrolysis cells (MEC) can produce hydrogen (H ₂ ) at a low energy expense, but H ₂ production rate is often limited by poor microbe-electrode interaction. This study aimed to enhance the interaction of microbes with a cathode electrode modified with an iron-sulfide (FeS) catalyst in MECs to achieve an efficient hydrogen evolution reaction (HER) and to optimize performance at different substrate concentrations, ranging from 1 g/L to 3 g/L of glucose. The electrochemical analysis revealed FeS a highly active catalyst for HER, surpassing the performance of a 10% platinum (Pt-C)-modified cathode. At 2g/L glucose, MECs with a FeS-modified cathode (MEC-FeS) produced hydrogen at the highest yield of 7.01 mol H ₂ /mol glucose, and the hydrogen production rate was 1.96 ± 0.09 m ³ /m ³ •d. The control operations of MEC with a pristine cathode and dark fermentation resulted in a reduced hydrogen yield of 5.83 ± 0.25 mol H ₂ /mol glucose and 2.12 ± 0.1 mol H ₂ /mol glucose, respectively. Moreover, the MEC-FeS achieved a high energy efficiency of 78 ± 5% when compared to the MEC without catalyst (60 ± 5%) and the dark fermentation (24 ± 1%). This study suggests that the utilization of FeS as a cathode catalyst in MECs can ensure high-rate hydrogen generation with optimal substrate concentration, paving the way for efficient upscaling and field application.