Your search keyword '"Specht ED"' showing total 2 results

1. Giant electromechanical coupling of relaxor ferroelectrics controlled by polar nanoregion vibrations.

Author

Manley ME, Abernathy DL, Sahul R, Parshall DE, Lynn JW, Christianson AD, Stonaha PJ, Specht ED, and Budai JD

Subjects

Electric Impedance, Electricity, Microscopy, Atomic Force, Neutron Diffraction, Titanium chemistry, Vibration, Magnets chemistry, Mechanical Phenomena, Nanostructures chemistry, Phonons

Abstract

Relaxor-based ferroelectrics are prized for their giant electromechanical coupling and have revolutionized sensor and ultrasound applications. A long-standing challenge for piezoelectric materials has been to understand how these ultrahigh electromechanical responses occur when the polar atomic displacements underlying the response are partially broken into polar nanoregions (PNRs) in relaxor-based ferroelectrics. Given the complex inhomogeneous nanostructure of these materials, it has generally been assumed that this enhanced response must involve complicated interactions. By using neutron scattering measurements of lattice dynamics and local structure, we show that the vibrational modes of the PNRs enable giant coupling by softening the underlying macrodomain polarization rotations in relaxor-based ferroelectric PMN-xPT {(1 - x)[Pb(Mg1/3Nb2/3)O3] - xPbTiO3} (x = 30%). The mechanism involves the collective motion of the PNRs with transverse acoustic phonons and results in two hybrid modes, one softer and one stiffer than the bare acoustic phonon. The softer mode is the origin of macroscopic shear softening. Furthermore, a PNR mode and a component of the local structure align in an electric field; this further enhances shear softening, revealing a way to tune the ultrahigh piezoelectric response by engineering elastic shear softening.

Published

2016

2. Phonon localization drives polar nanoregions in a relaxor ferroelectric.

Author

Manley ME, Lynn JW, Abernathy DL, Specht ED, Delaire O, Bishop AR, Sahul R, and Budai JD

Subjects

Crystallization, Neutron Diffraction, X-Ray Diffraction, Electricity, Iron Compounds chemistry, Nanostructures chemistry, Phonons

Abstract

Relaxor ferroelectrics exemplify a class of functional materials where interplay between disorder and phase instability results in inhomogeneous nanoregions. Although known for about 30 years, there is no definitive explanation for polar nanoregions (PNRs). Here we show that ferroelectric phonon localization drives PNRs in relaxor ferroelectric PMN-30%PT using neutron scattering. At the frequency of a preexisting resonance mode, nanoregions of standing ferroelectric phonons develop with a coherence length equal to one wavelength and the PNR size. Anderson localization of ferroelectric phonons by resonance modes explains our observations and, with nonlinear slowing, the PNRs and relaxor properties. Phonon localization at additional resonances near the zone edges explains competing antiferroelectric distortions known to occur at the zone edges. Our results indicate the size and shape of PNRs that are not dictated by complex structural details, as commonly assumed, but by phonon resonance wave vectors. This discovery could guide the design of next generation relaxor ferroelectrics.

Published

2014