A new avenue to relaxor-like ferroelectric behaviour found by probing the structure and dynamics of [NH 3 NH 2 ]Mg(HCO 2 ) 3

The field of relaxor ferroelectrics has long been dominated by ceramic oxide materials exhibiting large polarisations with temperature and frequency dependence. Intriguingly, the dense metal–organic framework (MOF) [NH 3 NH 2 ]Mg(HCO 2 ) 3 was reported as one of the first coordination frameworks to...

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Published in:Journal of materials chemistry. C, Materials for optical and electronic devices Materials for optical and electronic devices, 2023-07, Vol.11 (28), p.9695-9706
Main Authors: Hitchings, Thomas J., Wickins, Helen M., Peat, George U. L., Hodgkinson, Paul, Srivastava, Anant Kumar, Lu, Teng, Liu, Yun, Piltz, Ross O., Demmel, Franz, Phillips, Anthony E., Saines, Paul J.
Format: Article
Language:English
Subjects:
Cations
Ferroelectric materials
Ferroelectricity
Ferroelectrics
High temperature
Hydrogen bonding
Metal-organic frameworks
Neutron scattering
Neutrons
NMR
Nuclear magnetic resonance
Phase transitions
Polar environments
Protons
Relaxors
Single crystals
Temperature
Temperature dependence
Transition temperature
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Summary:The field of relaxor ferroelectrics has long been dominated by ceramic oxide materials exhibiting large polarisations with temperature and frequency dependence. Intriguingly, the dense metal–organic framework (MOF) [NH 3 NH 2 ]Mg(HCO 2 ) 3 was reported as one of the first coordination frameworks to exhibit relaxor-like properties. This work clarifies the origin of these relaxor-like properties through re-examining its unusual phase transition using neutron single crystal diffraction, along with solid-state NMR, quasielastic neutron scattering and dielectric spectroscopy studies. This reveals that the phase transition is caused by the partial reorientation of NH 3 NH 2 within the pores of the framework, from lying in the planes of the channel at lower temperatures to along the channel direction above the transition temperature. The transition occurs via a dynamic process such that the NH 3 NH 2 cations can slowly interconvert between parallel and perpendicular orientations, with an estimated activation energy of 50 kJ mol −1 . Furthermore these studies are consistent with proton hopping between the hydrazinium cations oriented along the channel direction via a proton site intermediate. This study suggests the ferroelectric properties of [NH 3 NH 2 ]Mg(HCO 2 ) 3 are likely driven by a hydrogen bonding mechanism. The relaxor behaviour is proposed to be the result of polar regions, which likely fluctuate due to increased cation dynamics at high temperature. The combination of cation reorientation and proton hopping fully describes this material's relaxor-like behaviour, suggesting a route to the future design of non-oxide-based relaxor ferroelectrics.
ISSN:2050-7526
2050-7534
DOI:10.1039/D3TC00480E