Solid oxide cells (SOC) play a major role in strategic visions to achieve decarbonization and
climate-neutrality. With its multifuel capability, this technology has received rapidly growing …

Protonic ceramic fuel cells and electrolysis cells represent low-and intermediate-
temperature electrochemical devices, which allow chemical-to-electrical energy conversion …

A traditional composite cathode for proton‐conducting solid oxide fuel cells (H‐SOFCs) is
typically obtained by mixing cathode materials and proton conducting electrolyte of BaCe0 …

Distribution of relaxation times (DRT) is a well-established method for deconvoluting
electrochemical impedance spectroscopy (EIS) data from fuel cells. DRT-analysis provides a …

Sr segregation on a perovskite oxide surface immensely affects the oxygen reduction activity
and the durability of solid oxide fuel cells cathode. Herein, a facile strategy is proposed …

Conventional electrochemical impedance spectroscopy (EIS) is a popular in-situ technique
for electrochemical analysis and has been widely applied in solid oxide cells (SOCs) …

Abstract New two-layer Ruddlesden—Popper (RP) oxide La 0.25 Sr 2.75 FeNiO 7− δ
(LSFN) in the combination of Sr 3 Fe 2 O 7− δ and La 3 Ni 2 O 7− δ was successfully …

Perovskite oxide molybdenum doped strontium ferrite, Sr 2 Fe 1.5 Mo 0.5 O 6-δ (SFM), is a
promising alternative hydrogen electrode material for solid oxide cells (SOCs) because of its …

The pure cubic perovskite structure of BaZr 0.1 Fe 0.9-x Ni x O 3-δ could be maintained
when the Ni-doping concentration is ranged from 15 to 20%. The characteristics of BaZr 0.1 …

Current perovskite oxide electrolytes, ie, acceptor-doped Ba (Ce, Zr) O3-δ, exhibit proton
conductivity ranging from 10− 3 to 10− 2 S cm− 1 at 600° C for protonic ceramic fuel cells …