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Multiaxial Multiferroicity with Large Spontaneous Polarization in a Hydroxyl-Modified Quinuclidinium Gallium(III) Chloride

Ze‐Jiang Xu, Wang Luo, Hua‐Kai Li, Mei-Ling Ren, Chao Shi, Na Wang, Heng‐Yun Ye, Le‐Ping Miao

2024Chemistry of Materials19 citationsDOI

Abstract

Organic–inorganic hybrid materials (OIHMs) have become a powerful platform for exploring ferroic materials due to the advantages of directional design on the molecular level. Here, based on a hybrid uniaxial ferroelectric (Quinuclidinium)GaCl 4 ( QGC ), a chiral hybrid ( R -3-hydroxylquinuclidinium)GaCl 4 ( R3HQGC ) was successfully synthesized through a molecular strategy of H/OH substitution. R3HQGC exhibits a much higher Curie temperature (318 K) than QGC (284 K) because hydroxyl modification enhances intermolecular interactions, increasing the movement energy barrier. Meanwhile, R3HQGC shows multiaxiality and multiferroicity (the coexistence of ferroelectricity and ferroelasticity). Notably, R3HQGC has a large spontaneous polarization (19.4 μC·cm –2 ) exceeding those of most multiferroics and multiaxial ferroelectrics. Our study presents an effective approach to promote ferroelectric properties and gives deep insight into exploring high-performance hybrid multiferroic materials.

Topics & Concepts

FerroelectricityMultiferroicsMaterials scienceFerroelasticityCurie temperatureHybrid materialPolarization (electrochemistry)NanotechnologyCondensed matter physicsOptoelectronicsFerromagnetismChemistryPhysical chemistryPhysicsDielectricPerovskite Materials and ApplicationsAcoustic Wave Resonator TechnologiesFerroelectric and Piezoelectric Materials