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Room-Temperature Anisotropic Actuation Driven by a Synergistic Order–Disorder and Displacive Phase Transition in a Ferroelectric Crystal

Ming‐Liang Jin, Xiang‐Bin Han, Chengdong Liu, Chao‐Yang Chai, Chang‐Qing Jing, Wei Wang, Chang‐Chun Fan, Jing‐Meng Zhang, Wen Zhang

2024Journal of the American Chemical Society28 citationsDOI

Abstract

Actuating materials convert different forms of energy into mechanical responses. To satisfy various application scenarios, they are desired to have rich categories, novel functionalities, clear structure–property relationships, fast responses, and, in particular, giant and reversible shape changes. Herein, we report a phase transition-driven ferroelectric crystal, ( rac -3-HOPD)PbI 3 (3-HOPD = 3-hydroxypiperidine cation), showing intriguingly large and anisotropic room-temperature actuating behaviors. The crystal consists of rigid one-dimensional [PbI 3 ] anionic chains running along the a -axis and discrete disk-like cations loosely wrapping around the chains, leaving room for anisotropic shape changes in both the b - and c -axes. The shape change is switched by a ferroelectric phase transition occurring at around room temperature (294 K), driven by the exceptionally synergistic order–disorder and displacive phase transition. The rotation of the cations exerts internal pressure on the stacking structure to trigger an exceptionally large displacement of the inorganic chains, corresponding to a crystal lattice transformation with length changes of +24.6% and −17.5% along the b - and c -axis, respectively. Single crystal-based prototype devices of circuit switches and elevators have been fabricated by exploiting the unconventional negative temperature-dependent actuating behaviors. This work provides a new model for the development of multifunctional mechanically responsive materials.

Topics & Concepts

ChemistryFerroelectricityPhase transitionCondensed matter physicsAnisotropyOrder (exchange)Crystal (programming language)Chemical physicsPhase (matter)NanotechnologyCrystallographyOptoelectronicsOpticsOrganic chemistryDielectricPhysicsComputer scienceProgramming languageMaterials scienceFinanceEconomicsSolid-state spectroscopy and crystallographyMaterial Dynamics and PropertiesLiquid Crystal Research Advancements