Colossal Negative Area Compressibility in the Ferroelastic Framework Cu(tcm)

Muzi Chen; Hanna L.B. Boström; Dominik Daisenberger; Nicholas P. Funnell; Christopher J. Ridley; Mohamed Mezouar; Claudia Weidenthaler; Andrew B. Cairns

doi:10.1021/jacs.5c02999

Colossal Negative Area Compressibility in the Ferroelastic Framework Cu(tcm)

Muzi Chen, Hanna L.B. Boström, Dominik Daisenberger, Nicholas P. Funnell, Christopher J. Ridley, Mohamed Mezouar, Claudia Weidenthaler, Andrew B. Cairns

Materials Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

Copper(I) tricyanomethanide, Cu(tcm), is a flexible framework material that exhibits the strongest negative area compressibility (NAC) effect ever observed─a remarkable property with potential applications in pressure sensors, artificial muscles, and shock-absorbing devices. Under increasing pressure, Cu(tcm) undergoes two sequential phase transitions (tetragonal → orthorhombic → monoclinic): It has an initial tetragonal structure (I4₁md) at ambient conditions, but this structure only persists within a narrow pressure range; at 0.12(3) GPa, a pressure-induced ferroelastic phase transition occurs, transforming Cu(tcm) into a low-symmetry orthorhombic structure (Fdd2). The orthorhombic phase has a NAC of −108(14) TPa^-1 in the b-c plane between 0.12(3) and 0.93(8) GPa. The NAC behavior is associated with framework hinge motion in a flexible framework with “wine-rack” topology. At 0.93(8) GPa, Cu(tcm) undergoes a second phase transition and transforms into a layered monoclinic structure (Cc) with topologically interpenetrating honeycomb networks. The monoclinic phase of Cu(tcm) exhibits a slight negative linear compressibility (NLC) of −1.1(1) TPa^-1 along the a axis and a zero area compressibility of K_ac = K_a + K_c = 0.0(4) TPa^-1 in the a-c plane over the pressure range of 0.93-2.63 GPa. In contrast to the orthorhombic phase, its mechanism is understood as the pressure-driven dampening of layer “rippling,” which acts to increase the cross-sectional area of the layer at higher hydrostatic pressures. These findings have implications for understanding the underlying mechanism of NAC phenomenon in framework materials.

Original language	English
Pages (from-to)	17946-17953
Number of pages	8
Journal	Journal of the American Chemical Society
Volume	147
Issue number	21
DOIs	https://doi.org/10.1021/jacs.5c02999
State	Published - May 28 2025

Funding

We thank the Science and Technology Facilities Council ISIS Neutron and Muon Source (STFC ISIS Facility) (data DOI: 10.5286/ISIS.E.RB2010698) and the Diamond Light Source (proposal number CY29285) for the provision of beamtime. We thank the European Synchrotron Radiation Facility (ESRF) for providing beamtime through ABC\u2019s postdoctoral fellowship. HLBB acknowledges financial support from the Swedish Research Council (VR, grant number 2022-02984) and the Wallenberg Initiative Materials Science for Sustainability (WISE), funded by the Knut and Alice Wallenberg Foundation. Open access funded by Max Planck Society. Open access funded by Max Planck Society.

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title = "Colossal Negative Area Compressibility in the Ferroelastic Framework Cu(tcm)",

abstract = "Copper(I) tricyanomethanide, Cu(tcm), is a flexible framework material that exhibits the strongest negative area compressibility (NAC) effect ever observed─a remarkable property with potential applications in pressure sensors, artificial muscles, and shock-absorbing devices. Under increasing pressure, Cu(tcm) undergoes two sequential phase transitions (tetragonal → orthorhombic → monoclinic): It has an initial tetragonal structure (I41md) at ambient conditions, but this structure only persists within a narrow pressure range; at 0.12(3) GPa, a pressure-induced ferroelastic phase transition occurs, transforming Cu(tcm) into a low-symmetry orthorhombic structure (Fdd2). The orthorhombic phase has a NAC of −108(14) TPa-1 in the b-c plane between 0.12(3) and 0.93(8) GPa. The NAC behavior is associated with framework hinge motion in a flexible framework with “wine-rack” topology. At 0.93(8) GPa, Cu(tcm) undergoes a second phase transition and transforms into a layered monoclinic structure (Cc) with topologically interpenetrating honeycomb networks. The monoclinic phase of Cu(tcm) exhibits a slight negative linear compressibility (NLC) of −1.1(1) TPa-1 along the a axis and a zero area compressibility of Kac = Ka + Kc = 0.0(4) TPa-1 in the a-c plane over the pressure range of 0.93-2.63 GPa. In contrast to the orthorhombic phase, its mechanism is understood as the pressure-driven dampening of layer “rippling,” which acts to increase the cross-sectional area of the layer at higher hydrostatic pressures. These findings have implications for understanding the underlying mechanism of NAC phenomenon in framework materials.",

author = "Muzi Chen and Bostr{\"o}m, {Hanna L.B.} and Dominik Daisenberger and Funnell, {Nicholas P.} and Ridley, {Christopher J.} and Mohamed Mezouar and Claudia Weidenthaler and Cairns, {Andrew B.}",

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AU - Boström, Hanna L.B.

AU - Daisenberger, Dominik

AU - Funnell, Nicholas P.

AU - Ridley, Christopher J.

AU - Mezouar, Mohamed

AU - Weidenthaler, Claudia

AU - Cairns, Andrew B.

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Colossal Negative Area Compressibility in the Ferroelastic Framework Cu(tcm)

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