A first-principles investigation of the linear thermal expansion coefficients of BeF$_2$: Giant thermal expansion

TL;DR

This study uses first-principles calculations to investigate the thermal expansion properties of BeF₂, revealing giant thermal expansion coefficients in certain phases driven by phonon mode behaviors and elastic properties.

Contribution

First-principles analysis of BeF₂ phases' thermal expansion, elastic, and dielectric properties, including prediction of giant thermal expansion coefficients and detailed phonon mode contributions.

Findings

BeF₂ exhibits giant linear thermal expansion in certain phases.

No negative thermal expansion observed in studied phases.

Elastic and dielectric properties of BeF₂ phases are reported for the first time.

Abstract

We present the results of a theoretical investigation of the linear thermal expansion coefficients (TECs) of BeF$_2$, within a direct Gruneisen formalism where symmetry-preserving deformations are employed. The required physical quantities such as the optimized crystal structures, elastic constants, mode Gruneisen parameters, and phonon density of states are calculated from first-principles. BeF$_2$ shows an extensive polymorphism at low pressures, and the lowest energy phases [$\alpha$-cristobalite with space group (SG) P$4_1 2_1 2$ and its similar phase with SG P$4_3 2_1 2$] are considered in addition to the experimentally observed $\alpha$-quartz phase. For benchmarking purposes, similar calculations are performed for the rutile phase of ZnF$_2$, where the volumetric TEC ($\alpha_v$), derived from the calculated linear TECs along the $a$ ($\alpha_a$) and $c$ ($\alpha_c$) directions, is in very good agreement with experimental data and previous theoretical results. For the considered phases of BeF$_2$, we do not find any negative thermal expansion (NTE). However we observe diverse thermal properties for the distinct phases. The linear TECs are very large, especially $\alpha_c$ of the $\alpha$-cristobalite phase and its similar phase, leading to giant $\alpha_v$ ($\sim 175 \times 10^{-6} {\rm K}^{-1}$ at 300 K). The giant $\alpha_v$ arises from large Gruneisen parameters of low-frequency phonon modes, and the C13 elastic constant that is negatively signed and large in magnitude for the $\alpha$-cristobalite phase. The elastic constants, high-frequency dielectric constants, Born effective charge tensors, and thermal properties of the above phases of BeF$_2$ are reported for the first time and hence serve as predictions.