The magnetocaloric effect and its most straightforward application, magnetic refrigeration,
are topics of current interest due to the potential improvement of energy efficiency of cooling …

Magnetic refrigeration relies on a substantial entropy change in a magnetocaloric material
when a magnetic field is applied. Such entropy changes are present at first‐order …

Electrocaloric cooling technologies, enabled by the discovery of the giant electrocaloric
effect in dielectrics more than a decade ago, represents a zero-global-warming-potential …

The prospect of efficient solid-state refrigeration at room temperature is driving research into
magnetic cooling engine design and magnetic phase transition-based refrigerants. I …

With advances in solid-state cooling materials in the past decade, non-vapor compression
technologies, or not-in-kind (NIK) cooling technologies have garnered great attention …

Advanced magnetic refrigerants such as La (Fe, Si) 13 materials require large entropy and
adiabatic temperature changes based on the control of phase change physics and …

Abstract Fully hydrogenated Mn containing LaFeSi alloys provide long time stability of
attractive magnetocaloric properties; issues of previously reported induced phase co …

Abstract (La, Ce)(Mn, Fe, Si) 13-based compounds which show a giant magnetocaloric
effect are potential materials for the cryogenic magnetic refrigeration. However, large …

Magnetic cooling prototypes based on the magnetocaloric effect require the magnetic
refrigerant to be shaped into geometries that enable quick and efficient heat-transfer to the …

Due to their excellent magnetocaloric properties hydrogenated La (Fe, Mn, Si) 13 are
considered as promising and cost efficient materials for active magnetic regenerators …