Nature Communications (Dec 2023)

Giant adiabatic temperature change and its direct measurement of a barocaloric effect in a charge-transfer solid

  • Shin-ichi Ohkoshi,
  • Kosuke Nakagawa,
  • Marie Yoshikiyo,
  • Asuka Namai,
  • Kenta Imoto,
  • Yugo Nagane,
  • Fangda Jia,
  • Olaf Stefanczyk,
  • Hiroko Tokoro,
  • Junhao Wang,
  • Takeshi Sugahara,
  • Kouji Chiba,
  • Kazuhiko Motodohi,
  • Kazuo Isogai,
  • Koki Nishioka,
  • Takashi Momiki,
  • Ryu Hatano

DOI
https://doi.org/10.1038/s41467-023-44350-4
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 12

Abstract

Read online

Abstract Solid refrigerants exhibiting a caloric effect upon applying external stimuli are receiving attention as one of the next-generation refrigeration technologies. Herein, we report a new inorganic refrigerant, rubidium cyano-bridged manganese–iron–cobalt ternary metal assembly (cyano-RbMnFeCo). Cyano-RbMnFeCo shows a reversible barocaloric effect with large reversible adiabatic temperature changes of 74 K (from 57 °C to −17 °C) at 340 MPa, and 85 K (from 88 °C to 3 °C) at 560 MPa. Such large reversible adiabatic temperature changes have yet to be reported among caloric effects in solid–solid phase transition refrigerants. The reversible refrigerant capacity is 26000 J kg−1 and the temperature window is 142 K. Additionally, cyano-RbMnFeCo shows barocaloric effects even at low pressures, e.g., reversible adiabatic temperature change is 21 K at 90 MPa. Furthermore, direct measurement of the temperature change using a thermocouple shows +44 K by applying pressure. The temperature increase and decrease upon pressure application and release are repeated over 100 cycles without any degradation of the performance. This material series also possesses a high thermal conductivity value of 20.4 W m−1 K−1. The present barocaloric material may realize a high-efficiency solid refrigerant.