English

On the microscopic mechanisms behind hyperferroelectricity

Materials Science 2021-02-03 v2

Abstract

Hyperferroelectrics are receiving a growing interest thanks to their unique property to retain a spontaneous polarization even in presence of a depolarizing field. Nevertheless, general microscopic mechanisms driving hyperferroelectricity, which is ascribed to the softening of a polar LOLO mode, are still missing. Here, by means of phonons calculations and force constants analysis in two class of hyperferroelectrics, the ABO3_3-LiNbO3-type systems and the prototypical hexagonal-ABC systems, we unveiled common features in the dynamical properties of a hyperferroelectric behind such LOLO instability: negative or vanishing on-site force constant associated to the cation driving the LOLO polar distortion, and destabilizing cation-anion interactions, both induced by short-range forces. We also predict possible enhancement of the hyperferroelectric properties by applying an external positive pressure; pressure strengthens the destabilizing short-range interactions. Particularly, the increase in the mode effective charges associated to the unstable LOLO mode under pressure suggests an eventual enhancement of the DD=0 polarization under compressive strain.

Keywords

Cite

@article{arxiv.2010.13091,
  title  = {On the microscopic mechanisms behind hyperferroelectricity},
  author = {Mohamed Khedidji and Danila Amoroso and Hania Djani},
  journal= {arXiv preprint arXiv:2010.13091},
  year   = {2021}
}
R2 v1 2026-06-23T19:37:44.052Z