Degradation behavior of galvanostatic and galvanodynamic cells for hydrogen production from high temperature electrolysis of water.

High temperature electrolysis of water using solid oxide electrochemical cells (SOEC) is a promising technology for hydrogen production with high energy efficiency and may promote decarbonization when coupled with renewable energy sources and excess heat from nuclear reactors. Apart from the technoeconomic considerations, commercial deployment of this technology critically depends on the long-term performance and durability of SOEC cells/stacks, especially under dynamic operations to withstand the intermittency of renewable energy. Herein, SOEC operation was conducted under galvanodynamic conditions and compared with galvanostatic cells to examine the effect on degradation behavior at an average current density of −0.75 A cm−2 at 750 °C. While dynamic operation shows no significant impact on the overall degradation rates compared to constant current operation, minor performance improvement was observed at potentials above 1.5 V when switched to galvanodynamic mode. The relatively lower overpotential during dynamic operation could not be explained by the negligible changes in the electrochemical impedance or cell temperature. Multiphysics modeling reveals that the oxygen partial pressure (P O2) in the electrolyte oscillates with the alternating current density under dynamic operations. The minor improvement in cell performance under dynamic mode might be associated with the relatively lower P O2 buildup as compared with that under galvanostatic operation. In addition, dynamic operation at high frequencies could effectively lower the extreme P O2 in the electrolyte, thus relieving stresses in the cells and alleviating cell degradation. [Display omitted] • P O2 buildup is major cause of SOEC degradation under current driven operation. • Multiscale modeling shows dynamic operation can alleviate P O2 buildup. • Dynamic operation shows stability and minor performance improvement. • Thermal imaging setup confirms consistency in cell temperature. • Modeling results suggest greater benefit at higher frequency/current. [ABSTRACT FROM AUTHOR]