Insights into high electric-field-induced strain in BiAlO3 modified Bi1/2Na1/2TiO3 films

Insights into high electric-field-induced strain in BiAlO3 modified Bi1/2Na1/2TiO3 films

The development of high-strain piezoelectric materials has presented a longstanding challenge, particularly in the development of high-strain polycrystalline lead-free piezoelectric thin films. In this work, we present a strategy for customizing the electrostrain in lead-free thin films through phas...

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Bibliographic Details
Main Authors: Muhammad Sheeraz, Sung Sik Won, Jong Pil Kim, Sabir Ali, Fazli Akram, Hyoung-Su Han, Bong Chan Park, Tae Heon Kim, Ill Won Kim, Aman Ullah, Chang Won Ahn
Format: Article
Language:English
Published: Tsinghua University Press 2025-03-01
Series:Journal of Advanced Ceramics
Subjects:
electrostrain
piezoelectrics
bi1/2na1/2tio3 (bnt)
bialo3 (ba)
thin films
phase transition
Online Access:https://www.sciopen.com/article/10.26599/JAC.2025.9221034
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Summary:The development of high-strain piezoelectric materials has presented a longstanding challenge, particularly in the development of high-strain polycrystalline lead-free piezoelectric thin films. In this work, we present a strategy for customizing the electrostrain in lead-free thin films through phase transition engineering. In this study, we achieved a high recoverable electrostrain in a Bi1/2Na1/2TiO3–BiAlO3 (BNT–BA) film. To accomplish this, ferroelectric BNT and BNT–BA films with identical thicknesses of 500 nm were fabricated on Pt(111)/TiO2/SiO2/Si(100) substrates via a sol-gel method. Compared with the BNT film, the BNT–BA film exhibited a greater polarization response and superior field strength endurance, maintaining the energy storage density beyond the breakdown field strength of the BNT. The BNT–BA film demonstrated a large unipolar strain of S = 0.43% with a normalized strain (maximum strain/maximum applied electric field (Smax/Emax)) of 203 pm/V, followed by an effective transverse piezoelectric coefficient (e31,f∗) of ~2.48 C/m2, which was more than two times greater than the value obtained for BNT (i.e., maximum strain/maximum applied electric field (Smax/Emax) = 72 pm/V and e31,f∗ of ~1.09 C/m2). This high strain response in the BNT–BA film can be attributed to the electric-field-induced phase transition of the mixed (i.e., cubic and rhombohedral) phases into rhombohedral and tetragonal phases (mainly the rhombohedral structure), which recover back to the original state when the electric field is removed. These findings suggest new pathways for achieving significant strain levels via alternative mechanisms, potentially enhancing the effectiveness and expanding the applications of piezoelectric materials.
ISSN:2226-4108
2227-8508

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