A review on recent developments in solar photoreactors for carbon dioxide conversion to fuels

Energy security, as well as global climate change, are the two interlinked concerns that demands attention. Solarassisted CO2 conversion potentially alleviates these problem by providing an efficient mode for storing energy. Among the several available methods, solar assisted phototechnology is notably an effective approach, as it takes a small amount of input energy and operates at low temperatures. This review includes a comprehensive study on the development of solar photoreactors to maximize yield for fuel production during carbon dioxide reduction. In the main stream, the general solar-driven carbon dioxide conversion methods are investigated to determine the suitable methodology for solar photoreduction of CO2 to methanol. The various photoreactors employed for solar photoreduction of carbon dioxide are evaluated and a comparative analysis is performed on different aspects of catalyst type, irradiation time, irradiated area, light intensity, and yield of methanol. Finally, the effect of parameters on the performance of solar-photoreactor is also accessed. The conclusions and future perspectives are presented which will open new path for further advances in the implementation of hybrid solar photoreactors to enhance the efficiency of CO2 photoreduction to fuel.

Automated summary

This review focuses on the development of solar photoreactors for maximizing fuel production through carbon dioxide reduction, with a special emphasis on solar photoreduction of CO2 to methanol. Various photoreactors are evaluated, and a comparative analysis is conducted on different aspects such as catalyst type, irradiation time, irradiated area, light intensity, and methanol yield. The conclusions and future perspectives presented aim to pave the way for enhancing the efficiency of CO2 photoreduction to fuel through the implementation of hybrid solar photoreactors.