These novel strategies will assist in the development of perovskites for sustainable energy and catalysis technologies. In line with global efforts towards cleaner energy technologies, fuel cells may ...

Electrochemical devices such as fuel cells are becoming indispensable for new power generation technologies because they can efficiently produce renewable energy. Ceramic proton conductors can be used ...

Proton conducting composite electrolytes represent a promising class of materials for intermediate temperature fuel cells, bridging the performance gap between low‐ and high‐temperature systems.

Proton conductors have emerged as a pivotal component in the development of intermediate temperature fuel cells, offering a promising alternative to conventional high-temperature electrolytes. These ...

The discovery of Ba 2 LuAlO 5 as a promising proton conductor paints a bright future for protonic ceramic fuel cells, report scientists from Tokyo Tech. Experiments show that this novel material has a ...

Donor doping into a mother material with disordered intrinsic oxygen vacancies, instead of the widely used strategy of acceptor doping into a material without oxygen vacancies, can greatly enhance the ...

(Nanowerk News) Donor doping into a mother material with disordered intrinsic oxygen vacancies, instead of the widely used strategy of acceptor doping into a material without oxygen vacancies, can ...

Researchers have developed a framework that uses machine learning to accelerate the search for new proton-conducting materials, that could potentially improve the efficiency of hydrogen fuel cells.

Tokyo Tech scientists showcased that donor doping within a mother material containing disordered intrinsic oxygen vacancies, as opposed to the commonly employed acceptor doping in vacancy-free ...

Scientists from the Tokyo Institute of Technology (Tokyo Tech) and High Energy Accelerator Research Organization (KEK) have developed a highly oxygen-deficient perovskite for protonic ceramic fuel ...

Scientists at the University of Manchester’s National Graphene Institute have found a mechanism to speed proton transport across graphene using light, which has the potential to completely change how ...