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Flexoelectricity-Driven Mechanical Switching of Polarization in Metastable Ferroelectrics

Ji Hye Lee, Hong Joon Kim, Jiyong Yoon, Sanghyeon Kim, Jeong Rae Kim, Wei Peng, Se Young Park, Tae Won Noh, Daesu Lee

2022Physical Review Letters13 citationsDOI

Abstract

Flexoelectricity-based mechanical switching of ferroelectric polarization has recently emerged as a fascinating alternative to conventional polarization switching using electric fields. Here, we demonstrate hyperefficient mechanical switching of polarization exploiting metastable ferroelectricity that inherently holds a unique mechanical response. We theoretically predict that mechanical forces markedly reduce the coercivity of metastable ferroelectricity, thus greatly bolstering flexoelectricity-driven mechanical polarization switching. As predicted, we experimentally confirm the mechanical polarization switching via an unusually low mechanical force (100 nN) in metastable ferroelectric CaTiO_{3}. Furthermore, the use of low mechanical forces narrows the width of mechanically writable nanodomains to sub-10 nm, suggesting an ultrahigh data storage density of ≥1 Tbit cm^{-2}. This Letter sheds light on the mechanical switching of ferroelectric polarization as a viable key element for next-generation efficient nanoelectronics and nanoelectromechanics.

Topics & Concepts

FlexoelectricityFerroelectricityPolarization (electrochemistry)Materials scienceMetastabilityCondensed matter physicsPolarization densityOptoelectronicsNanotechnologyPhysicsLiquid crystalDielectricMagnetic fieldChemistryPhysical chemistryQuantum mechanicsMagnetizationFerroelectric and Piezoelectric MaterialsAdvanced Sensor and Energy Harvesting MaterialsFerroelectric and Negative Capacitance Devices
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