Most microbial fuel cells (MFCs) based sensors rely on exoelectrogenic bacteria to sense contaminants. However, these sensors cannot monitor repeated pollutions unless the exoelectrogenic bacteria are recovered or re-inoculated. To overcome this drawback, a novel sediment microbial fuel cell (SMFC) based sensor was developed for online and in situ monitoring of repeated Cu2+ shocks to the overlaying water of paddy soil. The SMFC sensor was operated for a period of eight months in the field environment and a group of CuCl2 solutions ranging from 12.5 to 400 mg L-1 Cu2+ were repeatedly applied on sunny and rainy days in different seasons. Results show that the SMFC sensor generates one voltage peak in less than 20 s after each Cu2+ shock, regardless of the seasons and weather conditions, and the voltage increments from baseline to peak exhibit linear correlation (R2 > 0.92) with the logarithm of Cu2+ concentrations. Repeated Cu2+ pollutions do not decrease the baseline voltage, indicating that the activity of exoelectrogenic bacteria was not significantly inhibited. Soil adsorbed and inactivated approximately 99% of total Cu2+. Only 1% of total Cu2+ was the toxic exchangeable fraction, of which the concentrations were 0.73, 0.23, and 0.22 mg kg-1 in the surface (0-3 cm), middle (3-6 cm), and bottom (6-11 cm) layers, respectively. The abundance of 16S rRNA gene transcripts of exoelectrogenic bacteria-associated genera is the lowest in the surface layer (2.86 × 1011 copies g-1) and the highest in the bottom layer (7.99 × 1011 copies g-1). Geobacter, Clostridium, Anaeromyxobacter, and Bacillus are the most active exoelectrogenic bacteria-associated genera in the soil. This study suggests that the SMFC sensor could be applied in wetlands to monitor the repeated discharge of Cu2+ and other heavy metals.
Keywords: Clostridium; Electrical signal; Exoelectrogenic bacteria; Geobacter; SMFC.
Copyright © 2020 Elsevier B.V. All rights reserved.