English

Interface-Controlled Ferroelectricity at the Nanoscale

Materials Science 2015-06-25 v1

Abstract

Recent experimental results demonstrate that in thin films ferroelectricity persists down to film thickness of a few unit cells. This finding opens an avenue for novel electronic devices based on ultathin ferroelectrics, but also raises questions about factors controlling ferroelectricity and the nature of the ferroelectric state at the nanoscale. Here we report a first-principles study of KNbO3 ferroelectric thin films placed between two metal electrodes, either SrRuO3 or Pt. We show that the bonding at the ferroelectric-metal interface imposes severe constraints on the displacement of atoms, destroying the bulk tetragonal soft mode in thin ferroelectric films. This does not, however, quench local polarization. If the interface bonding is sufficiently strong the ground state represents a ferroelectric double-domain structure, driven by the intrinsic oppositely-oriented dipole moments at the two interfaces. Although the critical thickness for the net polarization of KNbO3 film is finite - about 1 nm for Pt and 1.8 nm for SrRuO3 electrodes - local polarization persists down to thickness of a unit cell.

Keywords

Cite

@article{arxiv.cond-mat/0510592,
  title  = {Interface-Controlled Ferroelectricity at the Nanoscale},
  author = {Chun-Gang Duan and Renat F. Sabirianov and Wai-Ning Mei and Sitaram S. Jaswal and Evgeny Y. Tsymbal},
  journal= {arXiv preprint arXiv:cond-mat/0510592},
  year   = {2015}
}

Comments

5 pages, 4 figures