The present study
reports about the fabrication of a three-dimensional
(3D) macroporous steel-based scaffold as an anode to promote specifically
bacterial attachment and extracellular electron transfer to achieve
power density as high as 1184 mW m–2, which is far
greater than that of commonly used 3D anode materials. The unique
3D open macroporous configuration of the anode and the microstructure
generated by the composite coating provide voids for the 3D bacterial
colonization of electroactive biofilms. This is attributed to the
sizeable interfacial area per unit volume provided by the 3D corrugated
electrode that enhanced the electrochemical reaction rate compared
to that of the flat electrode, which favors the enhanced mass transfer
and substrate diffusion at the electrode/electrolyte interface and
thereby increases the charge transfer by reducing the electrode overpotential
or interfacial resistance. In addition, bacterial infiltration into
the interior of the anode renders large reaction sites for substrate
oxidation without the concern of clogging and biofouling and thereby
improves direct electron transfer. A very low overpotential (−27
mV) with a very low internal resistance (7.104 Ω cm2) is achieved with the fabricated microbial fuel cell (MFC) that
has a modified 3D corrugated electrode. Thus, easier and faster charge
transfer at the electrode–electrolyte interface is confirmed.
The study presents a revolutionary practical approach in the development
of highly efficient anode materials that can ensure easy scale-up
for MFC applications.
The study of bacterial adhesion and its consequences has great significance in different fields such as marine science, renewable energy sectors, soil and plant ecology, food industry, and the biomedical field. Generally, the adverse effects of microbial surface interactions have attained wide visibility. However, herein, we present distinct approaches to highlight the beneficial aspects of microbial surface interactions for various applications rather than deal with the conventional negative aspects or prevention strategies. The surface microbial reactions can be tuned for useful biochemical or bio-electrochemical applications, which are otherwise unattainable through conventional routes. In this context, the present review is a comprehensive approach to highlight the basic principles and signature parameters that are responsible for the useful microbial−electrode interactions. It also proposes various surface tuning strategies, which are useful for tuning the electrode characteristics particularly suitable for the enhanced bacterial adhesion and reactions. The tuning of surface characteristics of electrodes is discussed with a special reference to the Microbial Fuel Cell as an example.
The performance of any bio-electrochemical system is dependent on the efficiency of electrode−microbial interactions. Surface properties play a focal role in bacterial attachment and biofilm formation on the electrodes. In addition to electrode surface properties, selective bacterial adhesion onto the electrode surface is mandatory to mitigate energy loss due to undesired bacterial interactions on the electrode surface. In the present study, microbial-patterned graphite scaffolds are developed for selective bacterial−electrode interactions. A power density as high as 1105 mW/m 2 is achieved with mG-E (a graphite electrode patterned with Escherichia coli), which is about 3 times higher than that of the pristine graphite electrode (370 mW/m 2 ). Initial mechanical pre-treatment of the graphite electrode, followed by bacterial patterning, results in the formation of a unique cobblestone topography with a tuned surface area of 127.12 m 2 /g. This provides suitable morphology with enhanced active sites for selective bacterial intercalation in graphite layers. This cannot be otherwise achieved by any mechanical or other means. A unique methodology of symbolic regression is adopted to validate a genetic algorithm suitable for predicting a perfect correlation between surface characteristics and electrochemical characteristics with a minimum root-mean-square error of 0.08. The bacterial intercalation onto the graphite electrode causes protuberance of the graphite layers that reduces the surface potential and resistance, leading to high electron transfer. The study presents a unique bacterial-inspired surface patterning on the anode, which is critical for the performance of a microbial fuel cell.
Electron transfer (ET) characteristics of the exoelectrogenic biofilm in the bacterial community is the rate limiting factor that decisively determines the efficiency of a microbial fuel cell (MFC). However, heterogeneities...
In spite of extensive merits associated with biochar-based carbon materials for microbial processes, it finds proportionally limited applications in the area of energy. The present study reports the strategic development...
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