Colossal barocaloric effects in the complex hydride Li2B12H12

Abstract

Traditional refrigeration technologies based on compression cycles of greenhouse gases pose serious threats to the environment and cannot be downscaled to electronic device dimensions. Solid-state cooling exploits the thermal response of caloric materials to external fields and represents a promising alternative to current refrigeration methods. However, most of the caloric materials known to date present relatively small adiabatic temperature changes (| T| 1 K) and/or limiting irreversibility issues resulting from significant phase-transition hysteresis. Here, we predict the existence of colossal barocaloric effects (isothermal entropy changes of | S| 100 JK-1kg-1) in the energy material Li2B12H12 by means of molecular dynamics simulations. Specifically, we estimate | S| = 387 JK-1kg-1 and | T| = 26 K for an applied pressure of P = 0.4 GPa at T = 475 K. The disclosed colossal barocaloric effects are originated by an order-disorder phase transformation that exhibits a fair degree of reversibility and involves coexisting Li+ diffusion and (BH)12-2 reorientational motion at high temperatures.