Abstract
We use a symmetry-motivated approach to analyse neutron pair distribution function data to investigate the mechanism of negative thermal expansion (NTE) in ReO$_3$. This analysis shows that the local structure of ReO$_3$ is dominated by an in-phase octahedral tilting mode and that the octahedral units are far less flexible to scissoring type deformations than the octahedra in the related compound ScF$_3$. These results support the idea that structural flexibility is an important factor in NTE materials, allowing the phonon modes that drive a volume contraction of the lattice to occupy a greater volume in reciprocal space. The lack of flexibility in ReO$_3$ restricts the NTE-driving phonons to a smaller region of reciprocal space, limiting the magnitude and temperature range of NTE. In addition, we investigate the thermal expansion properties of the material at high temperature and do not find the reported second NTE region. Finally, we show that the local fluctuations, even at elevated temperatures, respect the symmetry and order parameter direction of the observed $P4/mbm$ high pressure phase of ReO$_3$. The result indicates that the motions associated with rigid unit modes are highly anisotropic in these systems.
Highlights
The phenomenon of negative thermal expansion (NTE) is an intriguing and unusual property for a material to exhibit
The sign of the coefficient of thermal expansion in ScF3 has been shown to be highly sensitive to changes in the force constant governing flexing of the F−Sc−F right angle [24]. We investigate this hypothesis by using a symmetrymotivated approach to analyze neutron pair distribution function (PDF) data collected on ReO3 across its entire temperature range of stability
Analysis of the pair distribution functions was carried out using the symmetry-adapted PDF analysis (SAPA) method described in Ref. [35], in which we have provided a detailed worked example for isostructural ScF3
Summary
The phenomenon of negative thermal expansion (NTE) is an intriguing and unusual property for a material to exhibit. Soft-mode anisotropy in the negative thermal expansion material ReO3
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