Abstract

The prevalence of photosynthesis, as the major natural solar energy transduction mechanism or biophotovoltaics (BPV), has always intrigued mankind. Over the last decades, we have learned to extract this renewable energy through continuously improving solid-state semiconductive devices, such as the photovoltaic solar cell. Direct utilization of plant-based BPVs has, however, been almost impracticable so far. Nevertheless, the electrochemical platform of fuel cells (FCs) relying on redox potentials of algae suspensions or biofilms on functionalized anode materials has in recent years increasingly been demonstrated to produce clean or carbon-negative electrical power generators. Interestingly, these algal BPVs offer unparalleled advantages, including carbon sequestration, bioremediation and biomass harvesting, while producing electricity. The development of high performance and durable BPVs is dependent on upgraded anode materials with electrochemically dynamic nanostructures. However, the current challenges in the optimization of anode materials remain significant barriers towards the development of commercially viable technology. In this context, two-dimensional (2D) graphene-based carbonaceous material has widely been exploited in such FCs due to its flexible surface functionalization properties. Attempts to economically improve power outputs have, however, been futile owing to molecular scale disorders that limit efficient charge coupling for maximum power generation within the anodic films. Recently, Langmuir–Blodgett (LB) film has been substantiated as an efficacious film-forming technique to tackle the above limitations of algal BPVs; however, the aforesaid technology remains vastly untapped in BPVs. An in-depth electromechanistic view of the fabrication of LB films and their electron transference mechanisms is of huge significance for the scalability of BPVs. However, an inclusive review of LB films applicable to BPVs has yet to be undertaken, prohibiting futuristic applications. Consequently, we report an inclusive description of a contextual outline, functional principles, the LB film-formation mechanism, recent endeavors in developing LB films and acute encounters with prevailing BPV anode materials. Furthermore, the research and scale-up challenges relating to LB film-integrated BPVs are presented along with innovative perceptions of how to improve their practicability in scale-up processes.

Highlights

  • Booming energy demands and the exhaustion of toxic gases from conventional fuel sources compel research endeavors in the design and development of sustainable energy conversion devices with zero pollution

  • The primary photosynthesis process involves photocurrent production arising from the photosynthetic electron transfer chain (PETC) upon light irradiation

  • It could be understood that currently photosynthetic-based fuel cells (FCs) significantly lags behind conventional FCs in terms of power generation

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Summary

Introduction

Booming energy demands and the exhaustion of toxic gases from conventional fuel sources compel research endeavors in the design and development of sustainable energy conversion devices with zero pollution. Derivatives of graphene, such as GO [9–13], rGO [14–16] and graphene sheets (GS) [17,18], prepared in the form of thin films or sheets have shown significantly improved structural and surface dynamics These include lower density, high porosity, surface roughness, larger specific and relative surface area, hydrophobicity, excellent mechanical strength and electrochemical performance for high-performance electronics [19–23]. Graphene-based thin films have found various applications in electronics, photonics, energy generation and storage and in biology and medicine [24–29] In this context, various thin film-forming strategies, including template-directed assembly or chemical vapor deposition, self-assembly, electrochemical synthesis and centrifugal evaporationinduced methods have been developed. Various thin film-forming strategies, including template-directed assembly or chemical vapor deposition, self-assembly, electrochemical synthesis and centrifugal evaporationinduced methods have been developed These methods are generally tedious and lengthy, involving complicated chemical processes at high pressures and temperatures and/or requiring hazardous gases, contributing significantly to higher production cost [13,17,30].

Requirements
Summary
Graphene-Based LB Films for Fuel Cell Applications
Progress in Algae-Based Biophotovolatics and pore size with respect to its intended applications
Electrochemical
Findings
Conclusions

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