Multi-doped ceria-based composite as a promising low-temperature electrolyte with enhanced ionic conductivity for steam electrolysis

Steam electrolysis is one of the most efficient approaches for producing green hydrogen. This method is based on the application of solid oxide electrolysis cells (SOECs) fabricated from functional ceramic composites for water splitting at high temperatures. Gadolinium doped ceria (GDC) is a promising electrolyte material for the fabrication of SOECs. However, the effective sintering temperature for GDC composites is usually above 1250 °C, which makes it impossible to use conventional supporting materials like ferritic steel for stack fabrication. In this work, for the first time, we have developed a lithium-bismuth-copper co-doped GDC composite capable of sintering at ∼750 °C. The physicochemical and electrochemical characteristics of the co-doped GDC electrolyte were systematically analysed using thermogravimetric analysis (TG/DTA), Raman spectroscopy, SEM/EDX, XRD, EIS, XPS and dilatometry analysis. The fabricated electrolyte pellets sintered at 750 °C for 6 hours in an inert atmosphere (argon) showed high densification, obtaining 96.70% relative density. Also, the electrical conductivity obtained for the synthesised composite Ce 0.712 Gd 0.178 Li 0.05 Bi 0.05 Cu 0.01 O 1.801 (sintered at 950 °C for 6 h) was 29.6 mS cm −1 at 750 °C with activation energy as low as 0.13 eV. The result of this study helps to understand better the properties of co-doped electrolyte materials for the fabrication of more efficient steam electrolysers for environmentally-friendly hydrogen generation. A lithium-bismuth-copper co-doped GDC composite (Ce 0.712 Gd 0.178 Li 0.05 Bi 0.05 Cu 0.01 O 1.801 ) capable of sintering at ∼750 °C with an electrical conductivity of 29.6 mS cm −1 was developed for the first time for metal-supported solid oxide electrolysers.