Novel Mechanocaloric Materials for Solid-State Cooling Applications
Claudio Cazorla

TL;DR
This paper reviews recent advances in novel mechanocaloric materials, especially elastocaloric compounds, that could improve solid-state cooling by overcoming limitations of traditional materials like fatigue and hysteresis.
Contribution
It highlights new families of mechanocaloric materials, such as fast-ion conductors, plastic crystals, and multiferroics, with significant caloric effects and potential for practical cooling applications.
Findings
Elastocaloric materials show promising uniaxial stress-induced cooling.
Field-induced phase transitions in new materials offer large temperature shifts.
Multiferroics exhibit strong coupling of structural, magnetic, and polar properties.
Abstract
Solid-state cooling is an environmentally friendly and highly scalable technology that may solve most of the problems associated with current refrigerant methods. Solid-state cooling consists of applying external fields on caloric materials, which react thermally as a result of induced phase transformations. From an energy efficiency point of view, mechanocaloric compounds, in which the phase transitions of interest are driven by mechanical stresses, probably represent the most encouraging type of caloric materials. Conventional mechanocaloric materials like shape-memory alloys already display good cooling performances however in most cases they also present critical mechanical fatigue and hysteresis problems that limit their applicability. Finding new mechanocaloric materials and mechanisms able to overcome those problems while simultaneously rendering large temperature shifts, is…
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