Negative thermal expansion in transition-metal dicyanides: the hidden role of the underlying diamondoid framework

TL;DR

This study reveals that the negative thermal expansion in transition-metal dicyanides is driven by framework dynamics similar to diamond and silicon, challenging previous models focused on polyhedral rotations.

Contribution

It uncovers a hidden phonon dispersion in M(CN)$_2$ linked to the diamond-like framework, providing a new geometric model for NTE mechanisms.

Findings

All atoms exhibit similar thermal motion, indicating pseudo-spring behavior of cyanide linkages.

Phonon dispersion in M(CN)$_2$ closely resembles that of diamond and silicon.

A simple geometric model captures the key NTE physics at low temperatures.

Abstract

The transition-metal dicyanides M(CN)$_2$ (M = Zn, Cd) are amongst the most important negative thermal expansion (NTE) materials known, favoured for the magnitude, isotropy, and thermal persistence of the NTE behaviour they show. The conventional picture of the NTE mechanism in this family is one of correlated rotations and translations of M(C/N)$_4$ polyhedra acting to draw the diamondoid network of M--CN--M linkages in on itself. An implication of this mechanism is increased transverse vibrational motion of C and N atoms relative to the isotropic displacements of M atoms, which act as anchors. Here, we use a combination of neutron total scattering measurements and \emph{ab initio} calculations to reassess the vibrational behaviour of the M(CN)$_2$ family. We find that M, C, and N atoms all exhibit similar degrees of local thermal motion, such that the cyanide linkages behave as pseudo-springs connecting M$\ldots$M pairs. This interpretation leads us to uncover a `hidden' dispersion in the M(CN)$_2$ phonon dispersions, closely related to that of diamond and silicon themselves. By virtue of this mapping, a simple geometric model based on the competing energy scales of network stretching and flexing -- long applied to interpret NTE modes in C and Si -- turns out to capture the key NTE physics of M(CN)$_2$, especially at low temperatures. Our study highlights the potential insight gained by coarse-graining the complex lattice dynamics of framework materials in terms of what we call `framework modes' -- the correlated distortions of the underlying network structure itself.