Competing Hydrostatic Compression Mechanisms in Nickel Cyanide

Andrew B. Cairns; Andrew L. Goodwin; Annette K. Kleppe; Jasper Adamson; Joseph A. Hriljac; Matthew G. Tucker; Nicholas P. Funnell; Timothy C. Lucas

arxiv: 1507.02606 · v1 · pith:ODVKEFKQnew · submitted 2015-07-09 · ❄️ cond-mat.mtrl-sci

Competing Hydrostatic Compression Mechanisms in Nickel Cyanide

Jasper Adamson , Timothy C. Lucas , Andrew B. Cairns , Nicholas P. Funnell , Matthew G. Tucker , Annette K. Kleppe , Joseph A. Hriljac , Andrew L. Goodwin This is my paper

classification ❄️ cond-mat.mtrl-sci

keywords bulkcyanidenickelareaattributebasiscompetingcompressibilities

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We use variable-pressure neutron and X-ray diffraction measurements to determine the uniaxial and bulk compressibilities of nickel(II) cyanide, Ni(CN)$_2$. Whereas other layered molecular framework materials are known to exhibit negative area compressibility, we find that Ni(CN)$_2$ does not. We attribute this difference to the existence of low-energy in-plane tilt modes that provide a pressure-activated mechanism for layer contraction. The experimental bulk modulus we measure is about four times lower than that reported elsewhere on the basis of density functional theory methods [{\it Phys. Rev. B} {\bf 83}, 024301 (2011)].

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Competing Hydrostatic Compression Mechanisms in Nickel Cyanide

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