Abstract
The use of microbial fuel cells (MFCs) is quickly spreading in the fields of bioenergy generation and wastewater treatment, as well as in the biosynthesis of valuable compounds for microbial electrolysis cells (MECs). MFCs and MECs have not been able to penetrate the market as economic feasibility is lost when their performances are boosted by nanomaterials. The nanoparticles used to realize or decorate the components (electrodes or the membrane) have expensive processing, purification, and raw resource costs. In recent decades, many studies have approached the problem of finding green synthesis routes and cheap sources for the most common nanoparticles employed in MFCs and MECs. These nanoparticles are essentially made of carbon, noble metals, and non-noble metals, together with a few other few doping elements. In this review, the most recent findings regarding the sustainable preparation of nanoparticles, in terms of syntheses and sources, are collected, commented, and proposed for applications in MFC and MEC devices. The use of naturally occurring, recycled, and alternative raw materials for nanoparticle synthesis is showcased in detail here. Several examples of how these naturally derived or sustainable nanoparticles have been employed in microbial devices are also examined. The results demonstrate that this approach is valuable and could represent a solid alternative to the expensive use of commercial nanoparticles.
Highlights
In everyday life, energy plays an important part in sustaining processes required for life
Over the last few decades, the development of microbial electrochemical technologies has been very active and productive and is mainly represented by microbial fuel cells (MFCs) and microbial electrolysis cells (MECs) [2,3]. These devices can use the organic matter in residual biomass or wastewater to either produce usable electricity [4] or biosynthesize hydrogen [5]
Regardless of MFCs or MECs, the cost allocations for a device are represented by the anode, cathode, proton exchange membrane (PEM), reactor case, current collectors, and other costs
Summary
Energy plays an important part in sustaining processes required for life. The cost abatement needed to become feasible for use can only be achieved by excluding the use of noble metals and scavenging raw carbon materials from secondary or natural sources and transforming them into performant nanostructured materials using green synthesis routes that are cheap and effective Due to these driving reasons, and to overcome the problems arising from toxicity and low performance, green synthesis approaches are developing are attractive solutions in this regard. The second step is to use the eco-friendly synthesized materials as components in MFCs and MECs in order to demonstrate the real feasibility and performance that can be achieved with the simultaneous cost of these raw materials potentially being close to zero As a result, this overview is divided into two main parts: The first part of the overview deals with some interesting examples of how eco-friendly syntheses and natural and recycled sources can produce nanostructured/nanosized materials, with the second part highlighting and discussing the performances of nanomaterials obtained from green, sustainable, or recycled sources in MFCs and MECs
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