Mechanical Nanoscale Polarization Control in Ferroelectric PVDF-TrFE Films

Ferroelectric polymer films offer strong advantages like mechanical flexibility, biocompatibility, optical transparency, and low-cost processing. However, their dielectric or piezoelectric performance is often inferior to that of oxide ferroelectric materials. Key to the dielectric or piezoelectric performance of semicrystalline polymers is the enhancement of electric dipolar order that is naturally lower than in crystalline ferroelectrics. Here, reorientation and alignment of the electric polarization in thin films by the mechanical effect of a scanning unbiased force microscopy tip is demonstrated as a versatile tool for nanoscale domain writing. Thin films (50-150 nm) of PVDF-TrFE (78:22) on graphite are prepared with dense (110)-oriented beta-phase lamellae randomly oriented in the film plane. The in-plane polarization can be poled mechanically along any deliberately chosen direction in the film plane after vertical electric poling. Domain patterns with resolution down to approximate to 50 nm are written with four (out of six possible) local polarization orientations. Written domains show excellent long-time stability. The surface roughening from the mechanical treatment is moderate (rms roughness of 2-3 nm). A ferroelastic origin of the mechanical polarization switching is discussed. Finally, suggestions are made how to utilize the domain patterns in thin film devices.

Automated summary

This study demonstrates the reorientation and alignment of electric polarization in thin films using the mechanical effect of a scanning unbiased force microscopy tip. It shows that this method can be used to write stable domain patterns at the nanoscale, which can be utilized in thin film devices.