Mechanical Control of Polar Order

TL;DR

This study demonstrates that applying mechanical pressure to BiFeO3 thin films significantly reduces the electric field needed for polarization switching, enabling spontaneous switching and revealing new pathways for controlling multiferroic properties.

Contribution

It introduces a mechanically assisted polarization switching pathway in BiFeO3, showing how stress can lower energy barriers and enable new control methods for multiferroic devices.

Findings

Mechanical pressure reduces coercive voltage to near zero.

Stress suppresses ferroelastic domain competition.

Mechanically assisted switching enables lower energy polarization reversal.

Abstract

BiFeO3 is a model multiferroic in which the ferroelectric polarization is coupled to ferroelastic lattice distortions, yet deterministic control of its domain structure remains limited by high switching fields and competing polarization variants. Here, we identify a mechanically assisted polarization switching pathway in epitaxial BiFeO3 thin films that fundamentally alters the switching energetics. Using just out-of-plane electric fields, polarization reversal requires voltages of approximately 4 V and stabilizes coexisting polarization states. In contrast, when mechanical pressure is applied concurrently, the coercive voltage can be significantly reduced (even to 0V), resulting in spontaneous switching. Piezoresponse force microscopy measurements reveal that applied mechanical pressure suppresses ferroelastic domain competition, indicating a decrease in the required electrical energy barrier associated with polarization rotation and domain wall motion. These results demonstrate that stress acts as an active thermodynamic control parameter, enabling access to switching pathways that are inaccessible under only an electric field. By directly coupling lattice distortions to polarization reversal, mechanically assisted switching provides a general framework for controlling coupled order parameters in multiferroic oxides, which can be directly applied in the device-level architecture, where a small mechanical pressure can help in achieving lower switching energy of ferroelectric polarization. This work advances the fundamental understanding of electromechanical coupling in complex ferroics and establishes mechanical energy as a powerful tool for probing and manipulating ferroelastic ferroelectric interactions.