Interplay of Intersite Charge Transfer, Antiferromagnetism, and Strain in Barocaloric ACu3Fe4O12 Quadruple Perovskites

Abstract

We develop a minimal Landau theory for the concomitant intersite charge-transfer, antiferromagnetic, and isostructural phase transitions in ACu3Fe4O12 perovskites (A = La, Pr, Nd, Sm, Eu, Gd, Tb). The model incorporates the difference in average ligand-hole occupancy between Cu and Fe, the staggered magnetization of the Fe sublattice, volume strain, and intrinsic thermal expansion, together with their couplings. It qualitatively reproduces key thermodynamic properties of the ACu3Fe4O12 family, including the staggered magnetization, lattice volume, magnetic susceptibility, and the nearly linear temperature-pressure phase boundary. The framework predicts a pronounced elastic softening near the phase boundary, consistent with experiments where the bulk modulus of the low-pressure, charge-transferred antiferromagnetic phase exceeds that of the high-pressure, non-transferred paramagnetic phase. It also yields pressure-driven isothermal entropy changes, revealing that the intrinsic thermal expansion of the high- and low-temperature phases significantly shapes the overall barocaloric response. These results contrast with previous analyses of NdCu3Fe4O12, where thermal expansion was neglected in the entropy construction, and call for a reevaluation of barocaloric effects in quadruple perovskites.