The conversion of CO2 to fuels via electroreduction can be instrumental in reducing dependence on fossil fuels and contributes to the global targets of CO2 reduction. The electrochemical reduction of CO2 to hydrocarbons, however, is kinetically limited by the fact that it is a multi-step process, with each step requiring the transfer of multiple electrons. On the other hand, the high temperature electrochemical reduction of CO2 to CO using a solid oxide electrolysis cell (SOEC) provides a route that is both energy efficient and cost effective. The CO thus produced can act as a value added product, as it can be directly used as a fuel, or it can be reduced into hydrocarbons via the well-known Fischer-Tropsch process. Ni/YSZ based electrodes are fairly ubiquitous in the field of solid oxide technologies. We have proposed the infiltration of Cu into Ni/YSZ to generate Ni{Cu}x-YSZ type cathodes, which exhibit improved performance for CO2 electroreduction at high temperature (~800 oC). The electrodes are prepared on commercial standard YSZ supports using Ni{Cu}x-YSZ mixtures for cathode and LSM-YSZ mixture for anode.Most of the existing studies on high temperature reduction of CO2 on Ni/YSZ have been in the presence of safe gases, such as H2 or CO. The presence of H2 in the inlet stream created a reducing atmosphere on the electrode surface, and the reduction of CO2 proceeded through a thermochemical reverse water gas shift (RWGS) mechanism. (CO2 + H2 à CO + H2O). The presence of CO could lead to catalyst deactivation by Carbon deposition through Boudouard reaction (2CO à CO2 + C). Observations from such experiments led to the belief that metallic Ni in Ni/YSZ acts as the active species for CO2 reduction; and that the oxidation of the Ni to NiO leads to deactivation of the catalyst. By using operando Raman spectroscopy and online mass spectrometry, we have countered this idea and demonstrated that the electroreduction of CO2 on Ni-YSZ is mediated by a layer of NiOx on the electrode surface, which is the actual active species. CeOx is a well-known cathodic material for pure CO2 electroreduction. We have attempted to study the mechanistic aspects associated with CO2 electroreduction on Ce{M}Ox based systems as well. Figure 1