Ultrasensitive barocaloric material for room-temperature solid-state refrigeration

TL;DR

This paper reports a giant barocaloric effect in inorganic NH4I near room temperature, demonstrating its potential for efficient solid-state refrigeration with low pressure requirements and broad operational temperature range.

Contribution

It introduces a new inorganic material with unprecedented barocaloric strength and low driving pressure, advancing solid-state refrigeration technology.

Findings

Maximum entropy change of ~89 J K-1 kg-1 near room temperature

Very small saturation driving pressure of ~20 MPa

Broad temperature window of ~68 K under 80 MPa pressure

Abstract

Solid-state refrigeration based on caloric effects is an energetically efficient and environmentally friendly technology, which is deemed as a potential alternative to the conventional vapor-compression technology. One of the greatest obstacles to the real application is the huge driving fields. Here, we report a giant barocaloric effect in inorganic NH4I with maximum entropy changes of {\Delta}S_BCE^max ~89 J K-1 kg-1 around room temperature, associated with the orientationally order-disorder phase transition. The phase transition temperature, Tt, varies dramatically with pressure in a rate of dTt/dP ~0.81 K MPa-1, which leads to a very much small saturation driving pressure of {\Delta}P ~20 MPa, an unprecedentedly large caloric strength of |{\Delta}S_BCE^max/{\Delta}P| ~4.45 J K-1 kg-1 MPa-1, as well as a broad temperature window of ~68 K under an 80 MPa driving pressure. Comprehensive characterization of the crystal structure and dynamics by neutron scattering measurements reveals a strong reorientation-vibration coupling that is responsible for the large pressure sensitivity of Tt. This work is expected to advance the practical application of barocaloric refrigeration.