Rutile-Type Co0.5Ti0.5NbO4-Based Cathode with In Situ Exsolved Metal Particles for Direct CO2 Electrolysis.

ABSTRACT

Rutile-type Co0.5Ti0.5NbO4 (CTO)-based materials doped with Fe3+ or Ni2+ were investigated as cathode electrodes to modify their electrical conductivity and electrocatalysis toward CO2 splitting. Higher electric conductivity was found in Co0.4Fe0.2Ti0.4NbO4 (CTO-Fe, 0.78 S cm-1) and Co0.25Ni0.25Ti0.5NbO4 (CTO-Ni, 2.10 S cm-1) compared to CTO (0.49 S cm-1) after the reduction at 800 °C in Ar-5% H2. Co and Co-Ni particles exsolved in situ from the surface of CTO, CTO-Fe, and CTO-Ni after reduction. CTO-Ni and CTO-Fe cathodes did better in the CO2 electrolysis at 800 °C than the CTO one, but the CTO-Ni cell was unstable after 10 h of operation due to the carbon deposition that blocked the electrode. The cell with CTO-Fe demonstrated a good stability for CO2 splitting in 100 h. This work demonstrates that rutile-type CTO-based cathodes are promising to provide an efficient and candidate oxide cathode for the electrolysis of CO2.