Although they are emerging technologies for achieving high-efficiency and green and eco-
friendly energy conversion, ceramic electrochemical cells (CECs), ie solid oxide electrolysis …

Proton-conducting oxides are a class of solid-state ion-conducting ceramic materials that
demonstrate significant hydrogen ion (proton) conductivity at intermediate temperatures (eg …

A high‐performance cathode of a protonic ceramic fuel cell (PCFC) should possess
excellent oxygen reduction reactivity, high proton/oxygen‐ion/electron conductivity, and …

Meeting the escalating demand for clean water resources is one of the key challenges to
ensure a sustainable future. Catalysis plays an important role to advance the chemical …

Proton-conducting solid oxide electrolysis cells (H-SOECs) have attracted significant
attention in recent years. This is due to their advantageous nature compared with the …

As a consequence of the depletion of fossil fuels and an increasing population, the global
energy crisis has driven researchers to explore innovative energy storage and conversion …

FeCo nanoparticles exsolved from Co-doped Sm 0.9 FeO 3 nanofibers with abundant
oxygen vacancies (Vos) are proposed as an efficient electrocatalyst to promote nitrate …

Solid oxide fuel cells (SOFCs) are a promising technology for clean electricity generation.
However, their performance degradation over time and with thermal cycles due to thermal …

Perovskite oxides hold great promise as efficient electrocatalysts for various energy‐related
applications owing to their low cost, flexible structure, and high intrinsic catalytic activity …

The critical region determining the performance and lifetime of solid oxide electrochemical
systems is normally at the electrode side of the electrode/electrolyte interface. Typically this …