Structural Origin of Recovered Ferroelectricity in BaTiO$_3$ Nanoparticles

TL;DR

This study investigates the structural origins of enhanced ferroelectricity in 10 nm BaTiO3 nanoparticles, revealing large Ti off-centering and phase stabilization as key factors behind increased polarization.

Contribution

It provides a detailed structural model linking Ti off-centering and phase stabilization to ferroelectric enhancement in BaTiO3 nanoparticles.

Findings

Large Ti off-centering causes increased polarization.

Structural phase transitions are sharper in nanoparticles.

Oleate component stabilizes the polar phase.

Abstract

Nanoscale BaTiO3 particles (approximately 10 nm) prepared by ball-milling a mixture of oleic acid and heptane have been reported to have an electric polarization several times larger than that for bulk BaTiO3. In this work, detailed local, intermediate, and long-range structural studies are combined with spectroscopic measurements to develop a model structure of these materials. The X-ray spectroscopic measurements reveal large Ti off-centering as the key factor producing the large spontaneous polarization in the nanoparticles. Temperature-dependent lattice parameter changes reveal the sharpening of the structural phase transitions in these BaTiO3 nanoparticles compared to the pure nanoparticle systems. Sharp crystalline-type peaks in the barium oleate Raman spectra suggest that this component in the composite core-shell matrix, a product of mechanochemical synthesis, stabilizes an enhanced polar structural phase of the BaTiO3 core nanoparticles.