# Giant barocaloric effects in natural rubber: A relevant step toward   solid-state cooling

**Authors:** N. M. Bom, W. Imamura, E. O. Usuda, L. S. Paix\~ao, A. M. G. Carvalho

arXiv: 1705.10914 · 2018-04-24

## TL;DR

This paper demonstrates giant barocaloric effects in natural rubber, highlighting its potential as a low-cost, environmentally friendly material for solid-state cooling, with effects surpassing those of previously studied materials.

## Contribution

It reports the first observation of giant barocaloric effects in natural rubber, a polymer, expanding the scope of materials suitable for solid-state cooling technologies.

## Key findings

- Maximum entropy and temperature changes exceed previous materials.
- Natural rubber shows high normalized temperature change and refrigerant capacity.
- Barocaloric effects strongly depend on the glass transition in natural rubber.

## Abstract

Solid-state cooling based on i-caloric effects has shown to be a promising alternative to the conventional refrigeration devices. Only very recently, the research on barocaloric materials is receiving a deal of attention due to the demonstration of giant barocaloric effects in shape-memory alloys. Regarding polymers, there is still a lack of literature, despite their high caloric potential. Thus, we present here giant barocaloric effects in natural rubber, a low-cost and environmental friendly elastomer polymer. The maximum values of entropy and temperature changes are larger than those previously reported for any promising barocaloric material. Moreover, the huge normalized temperature change and refrigerant capacity exhibited by natural rubber confirm its high potential for cooling applications. We also verify a relevant dependence of the barocaloric effect on the glass transition in natural rubber. Our findings suggest that commercial refrigeration devices based on barocaloric effects from elastomer polymers can be envisaged in the near future.

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Source: https://tomesphere.com/paper/1705.10914