Login / Signup

Lead-free ferroelectrics with giant unipolar strain for high-precision actuators.

Xuefan ZhouJun ZhangHang LuoYan ZhangShiyu TangHou-Bing HuangXi YuanMiao SongHe QiDou Zhang
Published in: Nature communications (2024)
The trade-off between electrostrain and strain hysteresis for piezo/ferroelectric materials largely restrains the development of high precision actuators and remains unresolved over the past few decades. Here, a simple composition of (Bi 0.5 Na 0.5 ) 1-x/100 Sr x/100 TiO 3 in the ergodic relaxor state is collaboratively designed through the segregated domain structure with the ferroelectric core, local polarization heterogeneity, and defect engineering. The ferroelectric core can act as a seed to facilitate the field-induced nonpolar-to-polar transition. Together with the internal bias field caused by defect dipoles and adjusted through electric field cycling and heat treatment technology, a giant unipolar strain of 1.03% is achieved in the x = 30 ceramic with a low hysteresis of 27%, while the electric-field-independent large-signal piezoelectric strain coefficient of ~1000 pm/V and ultralow hysteresis of <10% can be obtained in the x = 35 ceramic. Intriguingly, the low-hysteresis high strain also exhibits near-zero remnant strain, excellent temperature and cycling stability.
Keyphrases
  • magnetic resonance imaging
  • single cell
  • heavy metals
  • quantum dots
  • risk assessment
  • replacement therapy
  • visible light