Dye-sensitized solar cells based on critical raw material-free Fe-N-C counter electrodes

Dye-sensitized solar cells (DSSCs) rely heavily on the counter electrode for their performance, which is responsible for collecting and transferring electrons generated at the photoanode. While platinum (Pt) has traditionally been used as a counter-electrode material, its cost, limited availability, and environmental concerns make it an unsuitable option for large-scale implementation. Iron-nitrogen--carbon (Fe-N-C) catalysts are receiving increasing attention due to their high catalytic activity and low cost. This study aims to investigate the performance of Fe-N-C materials as counter electrodes in DSSCs and assess their potential as a sustainable alternative to currently used platinum. Two different Fe-N-C-based materials have been synthesized using different carbon and nitrogen sources, and their electrochemical behavior has been assessed using current-voltage curves and impedance spectroscopy. The catalyst comprised a higher amount of iron and nitrogen shows higher efficiency and lower charge-transfer resistance due to improved iodide reaction kinetics and proper stability under potential cycling. However, this catalyst shows lower stability under a passive ageing procedure, which requires further clarification. Results provide new insights into the performance of Fe-N-C-based materials in DSSCs and aid in the further development of this promising technology.

Automated summary

Dye-sensitized solar cells (DSSCs) heavily rely on the counter electrode for their performance. Platinum (Pt) has been traditionally used as a counter-electrode material, but its limitations have led to the exploration of alternative materials such as iron-nitrogen-carbon (Fe-N-C) catalysts. This study investigates the performance of Fe-N-C materials as counter electrodes in DSSCs and provides insights for the development of this sustainable technology.