Since severe global warming and related climate issues have been caused by the extensive
utilization of fossil fuels, the vigorous development of renewable resources is needed, and …

In the past decade, intensive research on proton-conducting oxide materials has provided a
basis for the development of intermediate-temperature protonic ceramic electrochemical …

Hydrogen can be produced via many different technologies; however, from a safety
standpoint there exists no framework for selecting the right technology. Here, we provide a …

The potential for generating green hydrogen by electrolysis (water splitting) has resulted in a
substantial amount of literature focusing on lowering the current production cost of …

Green and energy-efficient buildings have gained wider acceptance in the last few years
due to their ability to save energy and, in certain cases, the ability to generate electricity …

Solid oxide fuel cells (SOFCs) and electrolysis cells (SOECs) are promising energy
conversion devices, on whose basis green hydrogen energy technologies can be …

The present work aims to identify critical materials in water electrolysers with potential future
supply constraints. The expected rise in demand for green hydrogen as well as the …

We present our efforts to scale up proton-conducting ceramic fuel cells (PCFCs) from the
button-cell level into small, multi-cell stacks. While recent advancements with lab-scale …

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

Proton-conducting ceramics are emerging as enabling materials for efficient electrochemical
electricity generation, energy storage, and fuels synthesis. In this work, we present longer …