A multiferroic on the brink: uncovering the nuances of strain-induced transitions in BiFeO$_3$

TL;DR

This review explores strain-induced phase transitions in BiFeO$_3$, focusing on the metastable super tetragonal phase, its structure, symmetry, and potential for enhanced magnetoelectric functionalities.

Contribution

It provides a comprehensive analysis of the structural, symmetry, and chemical factors influencing the T-phase in BiFeO$_3$, highlighting experimental challenges and future research directions.

Findings

Identification of the T-phase structure and symmetry

Role of chemistry in T-phase formation

Potential for large magnetoelectric responses

Abstract

Bismuth ferrite (BiFeO$_3$) is one of the very few known single-phase multiferroic materials. While the bulk compound is rhombohedral (R), the discovery of an epitaxial strain-induced structural transition into a so-called 'super tetragonal-phase' (T-phase) in this material incited a flurry of research activity focused on gaining an understanding of this phase transition and its possible functionalities. This metastable phase of BiFeO$_3$ is also multiferroic, with giant ferroelectric polarization and coexisting antiferromagnetic order, but above all it is the strain relaxation-induced phase mixtures and their outstanding piezoelectric and magnetoelectric responses which continue to intrigue and motivate the physicist and materials scientist communities. Here, we review the research into the T-phase and mixed-phase BiFeO$_3$ system. We begin with a brief summary of the history of the T-phase and an analysis of the structure of the various phases reported in the literature. We then address important questions regarding the symmetry and octahedral rotation patterns and the (as yet underexplored) important role of chemistry in the formation of the metastable T-phase. We follow by describing the phase transitions in this material, and how these may hold promise for large magnetoelectric responses. Finally we point out some experimental challenges inherent to the study of such a system, and potential pathways for how they may be overcome. It is our intention with this work to highlight important issues that, in our opinion, should be carefully considered by the community in order to use this fascinating materials system for a new paradigm of functionality.