A strategy for the enhancement of barocaloric performance in plastic crystal solid solutions

The drive for solid-state heating and cooling technologies is fuelled by their potential for enhanced sustainability and environmental impact compared to traditional vapour compression devices. The recent discovery of colossal barocaloric (BC) effects in the plastic crystal (PC) neopentyl glycol (NPG) has highlighted PCs as promising candidates for future solid-state thermal management. However, achieving optimal operational temperatures, low-pressure requirements, and substantial entropy changes in a single material remains challenging. Here, we demonstrate a strategy to address these constraints by forming a ternary solid solution of neopentyl PCs: NPG, pentaglycerine (PG) and pentaerythritol (PE). Notably, by including only a small quantity (2%) of the third component, we observe a seven-fold increase in reversible isothermal entropy change (|$\Delta S_{it,rev}$| = 13.4 J kg-1 K-1) and twenty-fold increase in operational temperature span ($\Delta T_{span }$ = 18 K) at pressures of 1 kbar, compared to pure NPG. The origin of these enhancements is revealed by quasielastic neutron scattering and synchrotron powder x-ray diffraction. We find a reduction in the activation energies of the rotational modes associated with the main entropic component of the BC effect, linked to a weakening of the intermolecular hydrogen bond network. This is proposed to improve the phase transition reversibility and operational temperature span by facilitating a broadened first-order phase transition, characterised by a significant phase co-existence region. These findings suggest an effective strategy for practicable molecular BCs, which is to design solid solutions that exploit the large compositional phase space of multi-component molecular systems.