Job Description
Protonic ceramic cells (PCC) have transformative potential as an electrochemical platform, capable of operating both as efficient fuel cells for power generation and as electrolysis cells for the sustainable production of fuels and chemicals using green electricity. Their intermediate operating temperatures of 400–600°C combined with similar class-leading efficiencies of higher temperature solid oxide cells (SOC) enable them to ease material and balance-of-plant constraints. In electrolysis mode, and in contrast to SOCs, steam and H2 are separated into different compartments in PCCs, which means various hydrogenation reactions can be performed in the H2 compartment within the cell. For instance, electrochemical conversion of N2 to NH3 and CO2 to CO and/or CH4 using only steam as an additional feedstock have already been demonstrated using PCCs.
In this postdoctoral position, you will contribute to the development, characterisation and testing of protonic ceramic cell technolog...