Origin of the colossal positive and negative thermal expansion in Ag3[Co(CN)6]: an ab initio density functional theory study

Origin of the colossal positive and negative thermal expansion in Ag3[Co(CN)6]: an ab initio density functional theory study

DFT calculations have been used to provide insights into the origin of the colossal positive and negative thermal expansion in Ag3[Co(CN)6]. The results confirm that the positive expansion within the trigonal basal plane and the negative expansion in the orthogonal direction are coupled due to the e...

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Bibliographic Details
Published in:Journal of physics. Condensed matter 2008-06, Vol.20 (25), p.255226-255226 (9)
Main Authors: Calleja, Mark, Goodwin, Andrew L, Dove, Martin T
Format: Article
Language:eng
Subjects:
Condensed matter: structure, mechanical and thermal properties
Exact sciences and technology
Inorganic compounds
Physics
Structure of solids and liquids
crystallography
Structure of specific crystalline solids
Thermal expansion
thermomechanical effects and density
Thermal properties of condensed matter
Thermal properties of crystalline solids
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Summary:DFT calculations have been used to provide insights into the origin of the colossal positive and negative thermal expansion in Ag3[Co(CN)6]. The results confirm that the positive expansion within the trigonal basal plane and the negative expansion in the orthogonal direction are coupled due to the existence of a network defined by nearly rigid bonds within the chains of Co-C-N-Ag-N-C-Co linkages. The origin of the colossal values of the coefficients of thermal expansion arise from an extremely shallow energy surface that allows a flexing of the structure with small energy cost. The thermal expansion can be achieved with a modest value of the overall Gruneisen parameter. The energy surface is so shallow that we need to incorporate a small empirical dispersive interaction to give ground-state lattice parameters that match experimental values at low temperature. We compare the results with DFT calculations on two isostructural systems: H3[Co(CN)6], which is known to have much smaller values of the coefficients of thermal expansion, and Au3[Co(CN)6], which has not yet been synthesized but which is predicted by our calculations to be another candidate material for showing colossal positive and negative thermal expansion.
ISSN:0953-8984
1361-648X