Solid‐state caloric effects as intrinsic thermal responses to different physical external stimuli
(magnetic‐, uniaxial stress‐, pressure‐, and electric‐fields) can achieve a higher energy …

Calls to minimize greenhouse gas emissions and demands for higher energy efficiency
continue to drive research into alternative cooling and refrigeration technologies. The caloric …

Magnetically driven thermal changes in magnetocaloric materials have, for several decades,
been exploited to pump heat near room temperature. By contrast, their electrocaloric and …

The phase‐down scenario of conventional refrigerants used in gas–vapor compressors and
the demand for environmentally friendly and efficient cooling make the search for alternative …

The ideal magnetocaloric material would lay at the borderline of a first-order and a second-
order phase transition. Hence, it is crucial to unambiguously determine the order of phase …

Magnetic, thermodynamic, neutron diffraction and inelastic neutron scattering are used to
study spin correlations in the easy-axis XXZ triangular lattice magnet K 2 Co (SeO 3) 2 …

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 …

The magnetocaloric effect of gadolinium has been measured directly in pulsed magnetic
fields up to 62 T. The maximum observed adiabatic temperature change is Δ T ad= 60.5 K …

The work is devoted to the study of the phenomenon of irreversibility of the magnetocaloric
effect (MCE) in the vicinity of the magnetostructural phase transition (PT) in Ni-Mn-Ga …

Magnetic refrigeration based on the magnetocaloric effect is expected to trigger
technological revolution in the refrigeration industry due to the merits of high energy …