Solid oxide electrolysis cell (SOEC) is a promising electrochemical device with high
efficiency for energy storage and conversion. However, the degradation of SOEC is a …

The development of proton-conducting solid oxide electrolysis cells for the intermediate-
temperature range application is largely hindered by the limited choice of adequate anode …

Colloidal gel and glass transitions are investigated using the idealized mode coupling
theory (MCT) for model systems characterized by short-range attractive interactions. Results …

Low power density and large temperature gradient are the key factors restricting the wider
adoption of solid oxide fuel cell stacks in powering vehicles. Placing inserts in the flow …

In solid oxide device operation, delamination and cracking cause more catastrophic damage
to cell life than other degradation mechanisms, leading to more rapid cell failure. The …

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 …

Ni redistribution in the hydrogen electrodes of solid oxide cells is an important degradation
mechanism. Its driving force is still under debate. This work focuses on the interplay between …

Microstructure evolution in a solid oxide fuel cell anode is strongly affected by operating
condition. The detailed mesoscale evolution mechanism under operating condition is still …

Due to the time required to test fuel cell degradation experimentally, a physics-based model
which can predict degradation can be a valuable tool. Grain coarsening and the resulting …

In the present study, an efficient approach for the prediction of Warburg-type element is
proposed via the analysis of the anode-supported solid oxide fuel cell (SOFC) performance …