Triggered ferroelectricity in HfO$_2$ from hybrid phonons (2502.08633v2)

Abstract: Ferroelectric HfO$_2$ has garnered significant attention for its promising application in high density nonvolatile data storage and nanoscale transistors. However, the uncertain origin of polarization in HfO$_2$ limits our ability to fully understand and control its ferroelectricity. The ongoing debate centers on whether HfO$_2$ is a proper or improper ferroelectric, as it exhibits characteristics of both types. In this study, we utilize symmetry-guided first-principles quantum mechanical (DFT) calculations to accurately map the energy landscape and identify the coherent switching pathway of HfO$_2$ by voltage. Our findings reveal two key insights. First, ferroelectricity in HfO$_2$ is driven by a triggered mechanism through coupling between the stable polar mode and hybrid non-polar modes. Second, unusually high polarization arises from the hybrid modes, which consists solely of non-polar modes. The results fundamentally transforms the perspective on polarization in HfO$_2$ and resolve conflicting characteristics observed, offering valuable guidance for superior technological applications.