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

Highlights Barocaloric methods offer the widest range among solid-state caloric materials
where to pick and choose. However, ideal barocaloric materials do not exist and a trade-off …

Several organic–inorganic hybrid materials from the metal–organic framework (MOF) family
have been shown to form stable liquids at high temperatures. Quenching then results in the …

Coordination polymers and metal–organic frameworks are now at the forefront of materials
science due to their abundant structural variability and facile functional tunability …

Barocaloric is the more recent among the caloric technologies employing solid-state
materials. The name derives from BaroCaloric Effect (BCE), the phenomenon responsible of …

Hybrid organic–inorganic perovskites (HOIPs) constitute unique coordination polymers with
a huge potential of transforming modern materials chemistry due to their wide applications …

Barocaloric materials have the potential to offer greener and more efficient alternatives to
conventional refrigerants that exploit vapor compression for cooling and heating …

Pressure-induced thermal changes in solids—barocaloric effects—can be used to drive
cooling cycles that offer a promising alternative to traditional vapor-compression …

Hybrid organic-inorganic perovskites (HOIPs) have attracted significant attention in recent
years attributed to their outstanding physical properties and striking application potentials in …

Hydrostatic pressure represents an inexpensive and practical method of driving caloric
effects in brittle magnetocaloric materials, which display first‐order magnetostructural phase …