Magnetism and magnetocaloric properties of Co1-xMnxCr2O4

Abstract

Co1-xMnxCr2O4 crystallizes as a normal spinel in the cubic Fd 3m space group, and the end members have been reported to display a region of collinear ferrimagnetism as well as a low-temperature spin-spiral state with variable coherence lengths from 3 nm to 10 nm in polycrystalline samples. Here, we present the synthesis of the entire solid solution, and data showing that the ferrimagnetic ordering temperature as well as the spin-spiral lock-in temperature are tunable with the Co/Mn ratio. The peak magnetocaloric entropy change was determined to be SM = -5.63 J kg-1 K-1 in an applied magnetic field change of H = 0 T to 5 T for the Mn end-member at the ferrimagnetic ordering temperature. Using density functional theory (DFT), we explore the shortcomings of the magnetic deformation proxy to identify trends in SM across composition in this spinel system, and explore future extensions of theory to address these discrepancies.