Solid oxide fuel cells (SOFCs) are widely recognized as efficient energy sources that have
the potential to shape the future of energy development. Among various types of SOFCs, the …

Electrochemical hydrogen devices like fuel cells are widely investigated as promising
technologies to mitigate the rising environmental challenges and enhance the renewable …

Compared with conventional oxygen-ion-conducting solid oxide fuel cells (O–SOFCs),
proton ceramic fuel cells (PCFCs) are more attractive for low-temperature operation due to …

The basic strategies of improving the stability of proton-conducting electrolytes based on
barium cerate (BaCeO 3) by means of:(i) co-do**,(ii) do** by nonmetallic elements and …

The characteristic of a number of oxide materials, which include BaCeO 3-systems, is their
ability to show the proton conductivity along with oxygen-ion conductivity. Such atypical …

High-temperature proton-conducting materials constitute a unique class of oxide materials,
which are able to exhibit protonic conductivity under hydrogen-containing atmospheres …

Abstract BaCe 0.5 Zr 0.3 Y 0.2 O 3–δ (BCZY), regarded as one of the most promising proton–
conducting electrolytes, often experiences difficulty because of its high sintering …

Solid oxide fuel cells with proton conducting electrolytes (H–SOFCs) show great potential for
more efficient energy conversion over their oxygen ionic conducting counterparts at …

Cathode materials are pivotal in advancing ceramic fuel cell (CFC) technology. However,
they still suffer from insufficient oxygen reduction reaction (ORR) activity and a high thermal …

Commercial use of solid oxide fuel cells (SOFCs) requires high output performance and
excellent long-term stability for cathode materials. A nanostructured spinel high-entropy …