Domain-wall Pinning and Defect Ordering in BiFeO Probed on the Atomic and Nanoscale

Overview

Journal Nat Commun

Specialty Biology

Date 2020 Apr 11

PMID 32273515

Citations 10

Authors

Andreja Bencan

Goran Drazic

Hana Ursic

Maja Makarovic

Matej Komelj

Tadej Rojac

Affiliations

Soon will be listed here.

Abstract

Electro-mechanical interactions between charged point defects and domain walls play a key role in the functional properties of bulk and thin-film ferroelectrics. While for perovskites the macroscopic implications of the ordering degree of defects on domain-wall pinning have been reported, atomistic details of these mechanisms remain unclear. Here, based on atomic and nanoscale analyses, we propose a pinning mechanism associated with conductive domain walls in BiFeO, whose origin lies in the dynamic coupling of the p-type defects gathered in the domain-wall regions with domain-wall displacements under applied electric field. Moreover, we confirm that the degree of defect ordering at the walls, which affect the domain-wall conductivity, can be tuned by the cooling rate used during the annealing, allowing us to determine how this ordering affects the atomic structure of the walls. The results are useful in the design of the domain-wall architecture and dynamics for emerging nanoelectronic and bulk applications.

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