Litcius/Paper detail

Enhanced Piezoelectric Response at Nanoscale Vortex Structures in Ferroelectrics

Xiaowen Shi, Nimish P. Nazirkar, Ravi Kashikar, Dmitry Karpov, Shola Folarin, Zachary Barringer, Skye Williams, Boris Kiefer, Ross Harder, Wonsuk Cha, Ruihao Yuan, Zhen Liu, Dezhen Xue, Turab Lookman, I. Ponomareva, Edwin Fohtung

2024ACS Applied Materials & Interfaces13 citationsDOIOpen Access PDF

Abstract

The piezoelectric response is a measure of the sensitivity of a material’s polarization to stress or its strain to an applied field. Using in operando X-ray Bragg coherent diffraction imaging, we observe that topological vortices are the source of a 5-fold enhancement of the piezoelectric response near the vortex core. The vortices form where several low-symmetry ferroelectric phases and phase boundaries coalesce. Unlike bulk ferroelectric solid solutions in which a large piezoelectric response is associated with coexisting phases in the proximity of the triple point, the largest responses for pure BaTiO 3 at the nanoscale are in spatial regions of extremely small spontaneous polarization at vortex cores. The response decays inversely with polarization away from the vortex, analogous to the behavior in bulk ceramics as the cation compositions are varied away from the triple point. We use first-principles-based molecular dynamics to augment our observations, and our results suggest that nanoscale piezoelectric materials with a large piezoelectric response can be designed within a parameter space governed by vortex cores. Our findings have implications for the development of next-generation nanoscale piezoelectric materials.

Topics & Concepts

PiezoelectricityVortexFerroelectricityMaterials scienceNanoscopic scalePolarization (electrochemistry)Condensed matter physicsPiezoelectric coefficientNanotechnologyOptoelectronicsPhysicsComposite materialDielectricMechanicsPhysical chemistryChemistryFerroelectric and Piezoelectric MaterialsMultiferroics and related materialsPhotorefractive and Nonlinear Optics