Persistent conductive footprints of 109 degrees domain walls in bismuth ferrite films

Using conductive and piezoforce microscopy, we reveal a complex picture of electronic transport at weakly conductive 109 degrees domain walls in bismuth ferrite films. Even once initial ferroelectric stripe domains are changed/erased, persistent conductive paths signal the original domain wall position. The conduction at such domain wall "footprints" is activated by domain movement and decays rapidly with time, but can be re-activated by opposite polarity voltage. The observed phenomena represent true leakage conduction rather than merely displacement currents. We propose a scenario of hopping transport in combination with thermionic injection over interfacial barriers controlled by the ferroelectric polarization. (C) 2014 AIP Publishing LLC.

Persistent conductive footprints of 109 degrees domain walls in bismuth ferrite films

Stress effects on the impedance and ferroelectricity of PVDF-BiFeO3-MWCNT films using xanthan gum as dispersant

Individual Barkhausen pulses of ferroelastic nanodomains

Origins of the macroscopic symmetry breaking in centrosymmetric phases of perovskite oxides

Stress effects on the impedance and ferroelectricity of PVDF-BiFeO3-MWCNT films using xanthan gum as dispersant

Origins of the macroscopic symmetry breaking in centrosymmetric phases of perovskite oxides

Individual Barkhausen pulses of ferroelastic nanodomains