Lattice dynamics and negative thermal expansion in the framework compound 
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 with two-dimensional and three-dimensional local environments

d'Ambrumenil, Stella; Zbiri, Mohamed; Chippindale, Ann M.; Hibble, Simon J.; Marelli, Elena; Hannon, Alex C.

doi:10.1103/physrevb.99.024309

Cited by 29 publications

(29 citation statements)

References 60 publications

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“…Notably, ZnM(CN) 4 (M=Pt, Pd, Ni) also exhibits a two‐fold interpenetrated PtS‐type topology network; however, it exhibits ideal tetrahedral Zn centers (average ϕ (T‐SP)=7.8 %) (Figure ) . In ZnNi(CN) 4 , the NTE behavior is observed with coefficients of α a = b =−21.2 MK −1 (M=10 −6 ), α c =+14.6 MK −1 , and α volume =−27.0 MK −1 ; where the coefficient of thermal expansion, α =d l / l d T ( l =lattice parameter, T =temperature) . These results led us to investigate the TE behavior of 1 by variable temperature synchrotron XRD measurements (wavelength=0.774638(1) Å) in the temperature range of 100–500 K (Figure ; Supporting Information, Figure S6 and Table S3).…”

Section: Resultsmentioning

confidence: 99%

“…Various cyanide‐bridged CPs, synthesized by combining cyanide‐metallate building blocks with metal ions, exhibit characteristic structure‐related properties, such as guest tunable magnetic properties, ion storage capabilities, and thermal expansion behaviors (TE), including negative thermal expansion (NTE) . The combination of Fe II with tetracyanide metallate units [M(CN) 4 ] 2− (M=Pt, Pd, Ni) could be a potential method for obtaining four‐coordinate Fe II nodes in FeM(CN) 4 ; however, such synthetic experiments often produced octahedral Fe II nodes coordinated to four equatorial cyanides and two other axial solvents/neutral ligands .…”

Section: Introductionmentioning

confidence: 99%

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Responsive Four‐Coordinate Iron(II) Nodes in FePd(CN)₄

et al. 2020

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Metal node design is crucial for obtaining structurally diverse coordination polymers (CPs) and metal-organic frameworks with desirable properties;h owever,F e II ions are exclusively six-coordinated. Herein, we present ac yanidebridged three-dimensional (3D) CP,F ePd(CN) 4 ,bearing fourcoordinate Fe II ions,which is synthesized by thermal treatment of at wo-dimensional (2D) six-coordinate Fe II CP,F e-(H 2 O) 2 Pd(CN) 4 •4 H 2 O, to remove water molecules.A tomicresolution transmission electron microscopyand powder X-ray and neutron diffraction measurements revealed that the FePd-(CN) 4 structure is composed of atwo-fold interpenetrated PtS topology network, where the Fe II center demonstrates an intermediate geometry between tetrahedral and square-planar coordination. This four-coordinate Fe II center with the distorted geometry can act as athermo-responsive flexible node in the PtS network.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Responsive Four‐Coordinate Iron(II) Nodes in FePd(CN)₄

et al. 2020

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“…Synchrotron-based pairdistribution-function (PDF) analysis and 13 C solid-state nuclear-magnetic-resonance (SSNMR) measurements were performed to build an adequate input structural model for the lattice-dynamical analysis and interpretation. This combined approach provides insight into the atomistic mechanisms of thermal expansion and has previously been used to study many other transitionmetal cyanides with unusual thermal properties [9][10][11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

Anomalous thermal expansion in one-dimensional transition metal cyanides: Behavior of the trimetallic cyanide Cu1/3Ag1/3
d'Ambrumenil
¹
,
Zbiri
²
,
Hibble
³

et al. 2019
Phys. Rev. B
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The structural dynamics of a quasi-one-dimensional (1D) mixed-metal cyanide, Cu1/3Ag1/3Au1/3CN, with intriguing thermal properties is explored. All the current known related compounds with straight-chain structures, such as group 11 cyanides CuCN, AgCN, AuCN and bimetallic cyanides MxM'1-xCN (M, M' = Cu, Ag, Au), exhibit 1D negative thermal expansion (NTE) along the chains and positive thermal expansion (PTE) perpendicular to them. Cu1/3Ag1/3Au1/3CN exhibits similar PTE perpendicular to the chains, however PTE, rather than NTE, is also observed along the chains. In order to understand the origin of this unexpected behavior, inelastic neutron scattering (INS) measurements were carried out, underpinned by lattice-dynamical density-functional-theory (DFT) calculations. Synchrotron-based pairdistribution-function (PDF) analysis and 13 C solid-state nuclear-magnetic-resonance (SSNMR) measurements were also performed to build an input structural model for the lattice dynamical study. The results indicate that transverse motions of the metal ions are responsible for the PTE perpendicular to the chains, as is the case for the related group 11 cyanides. However NTE along the chain due to the tension effect of these transverse motions is not observed. As there are different metal-to-cyanide bond lengths in Cu1/3Ag1/3Au1/3CN, the metals in neighboring chains cannot all be truly co-planar in a straight-chain model. For this system, DFT-based phonon calculations predict small PTE along the chain due to low-energy chain-slipping modes induced by a bondrotation effect on the weak metallophilic bonds. However the observed PTE is greater than that predicted with the straight-chain model. Small bends in the chain provide an alternative explanation for thermal behavior. These would mitigate the tension effect induced by the transverse motions of the metals and, as temperature increases and the chains move further apart, a straightening could occur resulting in the observed PTE. This hypothesis is further supported by unusual evolution in the phonon spectra, which suggest small changes in local symmetry with temperature.

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“…The mechanical properties of molecular crystals may differ from those of elemental solids, since the rotational degrees of freedom of molecules may play an important role [ 21 , 22 , 23 , 24 , 25 ]. There exist many examples of molecular crystals where rotations of molecules were analyzed [ 26 , 27 , 28 , 29 , 30 ].…”

Section: Introductionmentioning

confidence: 99%

Mechanical Properties of Cubene Crystals

et al. 2022

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The fullerene family, whose most popular members are the spherical C60 and C70 molecules, has recently added a new member, the cube-shaped carbon molecule C8 called a cubene. A molecular crystal based on fullerenes is called fullerite. In this work, based on relaxational molecular dynamics, two fullerites based on cubenes are described for the first time, one of which belongs to the cubic system, and the other to the triclinic system. Potential energy per atom, elastic constants, and mechanical stress components are calculated as functions of lattice strain. It has been established that the cubic cubene crystal is metastable, while the triclinic crystal is presumably the crystalline phase in the ground state (the potential energies per atom for these two structures are −0.0452 and −0.0480 eV, respectively).The cubic phase has a lower density than the monoclinic one (volumes per cubene are 101 and 97.7 Å3). The elastic constants for the monoclinic phase are approximately 4% higher than those for the cubic phase. The presented results are the first step in studying the physical and mechanical properties of C8 fullerite, which may have potential for hydrogen storage and other applications. In the future, the influence of temperature on the properties of cubenes will be analyzed.

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Lattice dynamics and negative thermal expansion in the framework compound ZnNi(CN)4 with two-dimensional and three-dimensional local environments

Cited by 29 publications

References 60 publications

Responsive Four‐Coordinate Iron(II) Nodes in FePd(CN)₄

Responsive Four‐Coordinate Iron(II) Nodes in FePd(CN)₄

Anomalous thermal expansion in one-dimensional transition metal cyanides: Behavior of the trimetallic cyanide Cu1/3Ag1/3
d'Ambrumenil
¹
,
Zbiri
²
,
Hibble
³

et al. 2019
Phys. Rev. B
Self Cite
5
1
11
1
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Mechanical Properties of Cubene Crystals

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Lattice dynamics and negative thermal expansion in the framework compound ZnNi(CN)4 with two-dimensional and three-dimensional local environments

Cited by 29 publications

References 60 publications

Responsive Four‐Coordinate Iron(II) Nodes in FePd(CN)4

Responsive Four‐Coordinate Iron(II) Nodes in FePd(CN)4

Anomalous thermal expansion in one-dimensional transition metal cyanides: Behavior of the trimetallic cyanide Cu1/3Ag1/3d'Ambrumenil1, Zbiri2, Hibble3 et al. 2019Phys. Rev. BSelf Cite51111View full textAdd to dashboardCite

Mechanical Properties of Cubene Crystals

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Responsive Four‐Coordinate Iron(II) Nodes in FePd(CN)₄

Responsive Four‐Coordinate Iron(II) Nodes in FePd(CN)₄

Anomalous thermal expansion in one-dimensional transition metal cyanides: Behavior of the trimetallic cyanide Cu1/3Ag1/3
d'Ambrumenil
¹
,
Zbiri
²
,
Hibble
³

et al. 2019
Phys. Rev. B
Self Cite
5
1
11
1
View full text Add to dashboard Cite