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Flexoelectric engineering of van der Waals ferroelectric CuInP <sub>2</sub> S <sub>6</sub>

Wenjie Ming, Boyuan Huang, Sizheng Zheng, Yinxin Bai, Junling Wang, Junling Wang, Jie Wang, Jie Wang, Jiangyu Li

2022Science Advances134 citationsDOIOpen Access PDF

Abstract

(CIPS) is an ideal candidate for developing two-dimensional microelectronic heterostructures because of its room temperature ferroelectricity, although field-driven polarization reversal of CIPS is intimately coupled with ionic migration, often causing erratic and damaging switching that is highly undesirable for device applications. In this work, we develop an alternative switching mechanism for CIPS using flexoelectric effect, abandoning external electric fields altogether, and the method is motivated by strong correlation between polarization and topography variation of CIPS. Phase-field simulation identifies a critical radius of curvature around 5 μm for strain gradient to be effective, which is realized by engineered topographic surfaces using silver nanowires and optic grating upon which CIPS is transferred to. We also demonstrate mechanical modulation of CIPS on demand via strain gradient underneath a scanning probe, making it possible to engineer multiple polarization states of CIPS for device applications.

Topics & Concepts

FlexoelectricityFerroelectricityMaterials scienceElectric fieldPolarization (electrochemistry)van der Waals forceMicroelectronicsCondensed matter physicsCurvaturePolarization densityStrain engineeringOpticsOptoelectronicsNanotechnologyPhysicsDielectricChemistrySiliconPhysical chemistryMagnetizationQuantum mechanicsMoleculeMathematicsGeometryMagnetic fieldNonlocal and gradient elasticity in micro/nano structuresFull-Duplex Wireless CommunicationsAcoustic Wave Resonator Technologies
Flexoelectric engineering of van der Waals ferroelectric CuInP <sub>2</sub> S <sub>6</sub> | Litcius