Ferroelectric Texture of Individual Barium Titanate Nanocrystals

Ferroelectric materials display exotic polarization textures at the nanoscale that could be used to improve the energetic efficiency of electronic components. The vast majority of studies were conducted in two dimensions on thin films, that can be further nanostructured, but very few studies address the situation of individual isolated nanocrystals synthesized in solution, while such structures could open other field of applications. In this work, we experimentally and theoretically studied the polarization texture of ferroelectric barium titanate (BaTiO$_3$, BTO) nanocrystals (NC) attached to a conductive substrate and surrounded by air. We synthesized NC of well defined quasi-cubic shape and 160 nm average size, that conserve the tetragonal structure of BTO at room temperature. We then investigated the inverse piezoelectric properties of such pristine individual NC by piezoresponse force microscopy (PFM), taking particular care of suppressing electrostatic artifacts. In all the NC studied, we could not detect any vertical PFM signal, and the maps of the lateral response all displayed larger displacements on the edges. Using field-phase simulations dedicated to ferroelectric nanostructures, we were able to predict the equilibrium polarization texture. These simulations revealed that the NC core is composed of 180{\deg} up and down domains defining the polar axis, that rotate by 90{\deg} in the two facets orthogonal to this axis, eventually lying within these planes forming a layer of about 10 nm thickness mainly composed of 180{\deg} domains along an edge. From this polarization distribution we predicted the lateral PFM response, that revealed to be in very good qualitative agreement with the experimental observations. This work positions PFM as a relevant tool to evaluate the potential of complex ferroelectric nanostructures to be used as sensors.