Direct observation of monoclinic polar nanoregions in the relaxor ferroelectric Pb(Yb$_{1/2}$Nb$_{1/2}$)O$_{3}$-PbTiO$_{3}$

TL;DR

This study reports the first direct observation of monoclinic polar nanoregions coexisting with monoclinic structures in a relaxor ferroelectric, revealing their growth with decreasing temperature and offering insights into relaxor ferroelectricity.

Contribution

It provides the first experimental evidence of monoclinic polar nanoregions in Pb(Yb$_{1/2}$Nb$_{1/2}$)O$_{3}$-PbTiO$_{3}$, linking relaxor properties with high piezoelectricity.

Findings

Polar nanoregions are randomly shaped and grow as temperature decreases.

Monoclinic Pm and Cm structures coexist in nanoregions, without rhombohedral phase.

The material exhibits relaxor behavior alongside high piezoelectricity.

Abstract

Relaxor ferroelectrics are applied in electronic devices such as actuators and sonars. Morphotrophic phase boundaries (MPBs) with monoclinic structures are known for their high piezoelectricity and electromechanical coupling factors in solid solutions of PbTiO$_{3}$ and relaxor ferroelectrics (Pb(Mg$_{1/3}$, Nb$_{2/3}$)O$_{3}$ or Pb(Zn$_{1/3}$, Nb$_{1/3}$)O$_{3}$). However, the monoclinic structures related to polar nanosize domains (polar nanoregions) exhibiting the relaxor properties of dielectric dispersion have not been reported. Using transmission electron microscopy and synchrotron x-ray scattering, we present the first observations of coexisting monoclinic structures and polar nanoregions near the MPB in Pb(Yb$_{1/2}$Nb$_{1/2}$)O$_{3}$-PbTiO$_{3}$. The polar nanoregions in this material are randomly shaped, unlike the ferroelectric nanodomains of the canonical relaxor Pb(Mg$_{1/3}$, Nb$_{1/3}$)O$_{3}$-PbTiO$_{1/3}$. Furthermore, in situ observations reveal that the monoclinic polar nanoregions grow as the temperature decreases. A pair-distribution function analysis reveals a mixture of monoclinic Pm and Cm structures in the polar nanoregions without the rhombohedral structure of other Pb-based relaxor solid solutions. Owing to the peculiar nature of the coexistence of the relaxor property (polar nanoregions) and high piezoelectricity (monoclinic structure), this material is expected as a new platform for understanding relaxor ferroelectricity.