Polarization switching mechanism in HfO2 from first-principles lattice mode analysis

Abstract

In this work, we carry out first-principles calculations and lattice mode analysis to investigate the polarization switching mechanism in HfO2. Because the stability of the polar orthorhombic Pca21 phase of HfO2 arises from a trilinear coupling, polarization switching requires the flipping of not only the polar 15Z mode, but also at least one zone-boundary anti-polar mode. The coupling between the polar and anti-polar modes thus leads to substantial differences among different polarization switching paths. Specifically, our lattice-mode-coupling analysis shows that paths in which the X2- mode is reversed involve a large activation energy, which because the X2- mode is nonpolar cannot be directly overcome by applying an electric field. Our results show that the anti-polar Pbca phase, whose structure is locally quite similar to that of the Pca21 phase, similarly cannot be transformed to this phase by an electric field as this would require local reversal of the X2- mode pattern. Moreover, for the domain wall structure most widely considered, propagation also requires the reversal of the X2- mode, leading to a much larger activation energy compared with that for the propagation of domain wall structures with a single sign for the X2- mode. Finally, these first-principles results for domain wall propagation in HfO2 have implications to many experimental observations, such as sluggish domain wall motion and robust ferroelectricity in thin films, and lattice mode analysis deepens our understanding of these distinctive properties of ferroelectric HfO2.