Fuel cells can efficiently convert the chemical energy in fuels like hydrogen and methane
into electricity and are an important component for the forthcoming hydrogen society …

The mixed protonic–electronic conducting (MPEC) ceramic membrane is crucial in hydrogen
separation technology due to its excellent hydrogen selectivity, high-temperature stability …

The commercial viability of protonic ceramic fuel cells (PCFCs) is contingent upon
develo** highly active and stable cathode materials. The conventional trial-and-error …

Protonic ceramic electrochemical cells (PCECs) are solid-state electrochemical devices that
employ proton-conducting oxides as electrolytes, which offer a promising approach for …

Protonic ceramic electrolysis cells (PCECs) are emerging as potential technology to achieve
efficient electrochemical hydrogen production and purification due to their high conversion …

Protonic ceramic electrochemical hydrogen pumps (PCEHPs) have garnered notice as a
promising technology for the hydrogen separation. However, the practical application of …

Yttrium stabilized zirconia (YSZ) as a typical oxygen ionic conductor has been widely used
as the electrolyte for solid oxide fuel cell (SOFC) at the temperature higher than 1000° C, but …

Protonic ceramic electrochemical hydrogen pump (PCEHP) is regarded as a “next
generation” technology for high pure hydrogen separation due to its advantages of high …

Power-to-methane technology enables storage of renewable electricity in chemical energy,
which can be transported and converted using existing infrastructure. The moderate energy …

A metal supported design is desirable for ceramic electrochemical cells because of its
robustness. Yet, a strong alkaline character and a refractory nature of the electrolyte material …