Condensation and Slow Dynamics of Polar Nanoregions in Lead Relaxors

TL;DR

This paper investigates the formation and slow dynamics of polar nanoregions in relaxor ferroelectrics using neutron and Raman scattering, revealing three stages of PNR evolution with temperature and proposing a coupling model based on PNR rotations.

Contribution

It introduces a comprehensive analysis of PNR condensation and dynamics in relaxors, including a new model explaining phonon behavior via PNR rotations.

Findings

Identification of three PNR evolution stages with temperature

Observation of PNR condensation and slow dynamics through scattering techniques

Proposed model linking phonon behavior to PNR reorientations

Abstract

It is now well established that the unique properties of relaxor ferroelectrics are due to the presence of polar nanoregions (PNR's). We present recent results from Neutron and Raman scattering of single crystals of PZN, PZN-xPT, and PMN. Both sets of measurements provide information on the condensation of the PNR's and on their slow dynamics, directly through the central peak and, indirectly, through their coupling to transverse phonons. A comparative analysis of these results allows identification of three stages in the evolution of the PNR's with decreasing temperature: a purely dynamic stage, a quasi-static stage with reorientational motion and a frozen stage. A model is proposed, based on a prior study of KTN, which explains the special behavior of the transverse phonons (TO and TA) in terms of their mutual coupling through the rotations of the PNR's.