Pressure-driven suppression of the Jahn–Teller effects and structural changes in cupric oxide

Abstract

Multiferroics have been of interest as materials for use in data storage due to their coexisting ferroelectric and ferromagnetic properties. The properties of cupric oxide have been studied at pressures below 70 GPa, and it has even been suggested that it may be a room temperature multiferroic at pressures of 20 to 40 GPa. However, the properties of cupric oxide above these pressures have yet to be thoroughly examined. Here, we investigate changes in the crystal structure of cupric oxide via first principles methods. We find that the crystal structure transforms from a monoclinic structure at low pressure to a face-centred cubic and body-centred cubic structure at high pressure. We also find that the magnetic ordering switches from antiferromagnetic in the monoclinic phase to net zero magnetic moment in the face-centred cubic phase and ferromagnetic in the body-centred cubic phase. This shift in magnetic ordering is due to the superexchange interactions and Jahn–Teller instabilities, or the lack of thereof, arising from the d-orbital electrons of the cupric ions, which disrupt the mechanical stability of other possible magnetic orderings.