Interfacial electron transfer for carbon dioxide valorization in hybrid inorganic-microbial systems

Converting carbon dioxide to value-added products with microbial electro- or photosynthesis has attracted significant interest in recent years for relieving global warming effects of fossil fuel use. Hybrid inorganicmicrobial systems have been developed to improve the efficiency and selectivity from electricity/solar energy of CO2 conversion. Microbes can acquire electrons from solid donors such as electrode or photosensitizers, understanding the electron transfer mechanisms between inorganic catalysts and microbes is important for designing hybrid systems. However, few reviews have comprehensively summarized the electron transfer mechanisms of hybrid inorganic-microbial interfaces. In this critical review, we classify the electron transfer mechanism of CO2 reduction in hybrid inorganic-microbial systems into direct and indirect pathways. For direct electron transfer, when inorganic catalysts locate on the surface of a cell, electrons transfer from cathode or/and catalysts to the cell via proteins, this process is extracellular electron transfer; when inorganic catalysts are coupled with microbes intracellularly, electrons generate inside the cell and then transfer directly to metabolic pathways, this process is intracellular electron transfer. For indirect electron transfer, the basis of classification is whether redox electron mediators or reductive intermediate products can transfer electrons from inorganic catalysts to microbes. Moreover, the roles of inorganic catalysts and microbes are illustrated in detail to improve the CO2 conversion effectivity and selectivity. Based on this review, the interactions between various inorganic materials and microbes can be understood more clearly, and future research on the reduction of CO2 could be put forward.

Automated summary

This review discusses the electron transfer mechanisms in converting carbon dioxide to value-added products using microbial electro- or photosynthesis, categorizing them into direct and indirect pathways. It reveals the crucial roles of inorganic catalysts and microbes in enhancing the efficiency and selectivity of CO2 conversion.