High-efficiency elastocaloric refrigeration requires high-performance elastocaloric materials
with both large surface areas to promote heat exchange rate and large elastocaloric effects …

Ti–Ni based shape memory alloys are promising elastocaloric materials for solid-state
refrigeration. In this paper, we made a comprehensive study on elastocaloric effect of a …

The stress-induced martensitic phase transformation of shape memory alloys (SMAs) is the
basis for elastocaloric cooling. Here we employ additive manufacturing to fabricate TiNi …

Elastocaloric cooling technology based on shape memory alloys (SMAs) exploits the caloric
effect generated by stress-induced phase transformation of elastocaloric materials to realize …

Solid-state elastocaloric cooling, exploiting the latent heat yielded by superelastic
martensitic transformation, represents a very promising substitute for the conventional vapor …

Exploration of high-performance elastocaloric materials is of great significance to the
development of environmentally friendly mechanocaloric cooling technology that could …

Elastocaloric cooling using shape memory alloys is a promising candidate for next-
generation environmentally friendly refrigeration. The temperature lift (T lift), that is, the …

Abstract Development of high-performance advanced elastocaloric materials is essential for
the execution of elastocaloric refrigeration that can be an environment-friendly and high …

Ni–Mn-based shape memory alloy is a promising candidate as the solid-state elastocaloric
refrigerant in the micro-or nano-refrigeration fields owing to the required small driving force …

Elastocaloric cooling is emerging as one of the most promising alternatives to vapor-
compression cooling technology. It is based on the elastocaloric effect (eCE) of shape …