An integrated assessment of microfluidic microbial fuel cell subjected to vibration excitation

Microfluidic microbial fuel cell is considered as a new development direction of green and sustainable energy systems. Compared with other microbial electrochemical reactors, microfluidic microbial fuel cells have lower cost and higher energy efficiency. In practice, vibration is a non-negligible factor affecting the performance of microfluidic microbial fuel cell. However, numerical studies in this area are lacking. In the current work, a two-dimensional transient model for microfluidic microbial fuel cell is established by coupling the vibration force field with hydrodynamics, mass transfer, whole-cell electrochemical reaction kinetics and microbial growth. The correctness of the model is guaranteed by comparing the experimental data with simulation results. After model validation, an integrated assessment of the vibration effect on microfluidic microbial fuel cell is obtained. Major conclusions show that vibration excitation can inhibit the growth of electricigens inside the anode, thus reducing the output performance of microfluidic microbial fuel cell. Increasing the vibration intensity and frequency will exacerbate this effect. However, appropriate vibration excitation is beneficial to the substrate removal of microfluidic microbial fuel cell. Vibration will destroy the laminar flow pattern in the microchannel and increase the bacteria concentration inside the cathode. Additionally, the increment of feed flow rate is conductive to enhancing the anti-vibration ability of the cell

Automated summary

Microfluidic microbial fuel cells are a promising development in green and sustainable energy systems, with lower cost and higher energy efficiency compared to other microbial electrochemical reactors. However, the impact of vibration on the performance of microfluidic microbial fuel cells has not been extensively studied. This work establishes a two-dimensional transient model that incorporates vibration, hydrodynamics, mass transfer, electrochemical reactions, and microbial growth to assess the vibration effect on microfluidic microbial fuel cells.