Negative thermal expansion near the precipice of structural stability in open perovskites

TL;DR

This paper reviews negative thermal expansion in open perovskites, highlighting its origin from lattice dynamics near structural quantum phase transitions and discussing the influence of disorder.

Contribution

It introduces a theoretical model linking SNTE to proximity to structural quantum phase transitions and phase fluctuations in open perovskites.

Findings

NTE occurs near competing structural phases.

SNTE is maximized near structural quantum phase transitions.

Disorder affects NTE and phase stability.

Abstract

Negative thermal expansion (NTE) describes the anomalous propensity of materials to shrink when heated. Since its discovery, the NTE effect has been found in a wide variety of materials with an array of magnetic, electronic and structural properties. In some cases, the NTE originates from phase competition arising from the electronic or magnetic degrees of freedom but we here focus on a particular class of NTE which originates from intrinsic dynamical origins related to the lattice degrees of freedom, a property we term \textit{structural} negative thermal expansion (SNTE). Here we review some select cases of NTE which strictly arise from anharmonic phonon dynamics, with a focus on open perovskite lattices. We find that NTE is often present close in proximity to competing structural phases, with structural phase transition lines terminating near $T$=0 K yielding the most superlative displays of the SNTE effect. We further provide a theoretical model to make precise the proposed relationship among the signature behavior of SNTE, the proximity of these systems to structural quantum phase transitions and the effects of phase fluctuations near these unique regions of the structural phase diagram. The effects of compositional disorder on NTE and structural phase stability in perovskites are discussed.