Mesoscopic Helices of Polar Domains in a Quadruple Perovskite

TL;DR

This paper reports the discovery of a mesoscopic helical pattern of polar domains in a quadruple perovskite, revealing a new mechanism for inducing chirality in ferroelectric materials through self-organized domain arrangements.

Contribution

It introduces a novel mesoscopic helical order of polar domains in a ferroelectric crystal, expanding understanding of helical textures beyond magnetic systems.

Findings

Observation of both right- and left-handed helical polar domains.

Rejection of previously claimed helical dipole modulation in similar materials.

Establishment of mesoscopic ordering as a new mechanism for chirality in ferroelectrics.

Abstract

A significant effort in condensed matter physics is dedicated to the search for exotic arrangements of electric dipoles in crystals. Non-collinear dipolar arrangements mimicking magnetic spin textures, such as polar vortices and skyrmions, have been realized, but others, like helices of dipoles, have remained elusive. While earlier work claimed the presence of a helical dipole modulation in ferroelectric BiCu$_{x}$Mn$_{7-x}$O$_{12}$, our results rule out such a structure, motivating a renewed search for helical textures. Using atomic-resolution imaging, we report a novel form of helical order in which polar domains self-organize into a mesoscopic helical pattern: from domain to domain, polarization rotation follows a consistent handedness. Both right- and left-handed chirality emerging from this helical ordering are observed. This discovery establishes mesoscopic ordering as novel mechanism for inducing helical textures, and hence chirality, in ferroelectric crystals, paralleling the efforts in liquid crystals and supramolecular assemblies.