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Ultrahigh field-induced strain in lead-free ceramics

Jiyue Wu, Haibin Zhang, Chang-Hsun Huang, Chiao‐Wei Tseng, Nan Meng, Vladimír Kovaľ, Yi‐Chia Chou, Zhen Zhang, Haixue Yan

2020Nano Energy152 citationsDOIOpen Access PDF

Abstract

Due to the worldwide concerns of environmental protection and sustainable development, lead-free piezoelectric materials are greatly desired for bridging the electrical energy to the mechanical energy. However, their lower energy conversion coefficient compared to the conventional lead-containing piezoelectric materials significantly limits their device applications. Herein, we introduce a novel strategy to increase the strain of lead-free ferroelectric system via material structure design to create polar nano regions (PNRs) and point defects in the material while retaining the global ferroelectric phase. This added short-range structural heterogeneity in the material will facilitate the field-induced phase transition and reversible domain wall switching to enhance the strain. Following this strategy, we demonstrate an ultrahigh strain induced by an electric field in non-textured lead-free Bi0.5Na0.5TiO3 (BNT)-based ceramics. The strain in unipolar mode (Suni) can reach up to 0.74% at 70 kV/cm, making it the highest value in reported lead-free ceramics so far. This puts forward a good route to design high-performance piezoelectric materials by material structure engineering. It also reveals the promising potential of lead-free piezoelectric materials in practical electromechanical device applications.

Topics & Concepts

Materials sciencePiezoelectricityFerroelectricityLead (geology)CeramicPiezoelectric coefficientBridging (networking)Composite materialStrain engineeringEngineering physicsNanotechnologyOptoelectronicsDielectricComputer scienceComputer networkSiliconGeologyGeomorphologyEngineeringFerroelectric and Piezoelectric MaterialsDielectric materials and actuatorsMultiferroics and related materials
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