English

A Self-Consistent Computational Framework for Displacive Ferroelectrics from the Condensed Ground State

Materials Science 2026-05-05 v5

Abstract

Quantitative description of finite-temperature properties of displacive ferroelectrics, and in particular the critical behavior, is of fundamental importance to both theory and device design, going beyond the Landau-Ginzburg approach, which requires known knowledge of critical behaviors and temperature-dependent parameter fitting. Here within quantum statistic description of polarization fluctuations, we develop a self-consistent, microscopically based computationalframework for finite-temperature thermodynamics and phase transitions in displacive ferroelectrics. It enables one to use only the ground-state properties to predict the finite-temperature properties and in particular, the criticality of phase transitions of various displacive ferroelectrics. Its applications to the classical ferroelectric PbTiO3_3, quantum paraelectrics SrTiO3_3 and KTaO3_3, and recently fabricated ferroelectric strained SrTiO3_3, demonstrate remarkable quantitative agreements with the experimentally measured dielectric/ferroelectric properties throughout the entire temperature ranges of the phases, including the critical behaviors of phase transitions. The proposed computational framework offers a tractable quantitative basis for bridging microscopic ground-state modeling and macroscopic device-level design in a broad range of ferroelectric systems under diverse thermodynamic and external conditions.

Keywords

Cite

@article{arxiv.2412.04308,
  title  = {A Self-Consistent Computational Framework for Displacive Ferroelectrics from the Condensed Ground State},
  author = {F. Yang and L. Q. Chen},
  journal= {arXiv preprint arXiv:2412.04308},
  year   = {2026}
}

Comments

21 pages, 5 figures

R2 v1 2026-06-28T20:24:27.461Z