The atomic-level response of zigzag ferroelectric domain walls (DWs) was investigated with in situ bias scanning transmission electron microscopy (STEM) in a subcoercive-field regime. Atomic-level movement of a single DW was observed. Unexpectedly, the change in the position of the DW, determined from the atomic displacement, did not follow the position of the strain field when the electric field was applied. This can be explained as low mobility defect segregation at the initial DW position, such as ordered clusters of oxygen vacancies. Further, the triangular apex of the zigzag wall is pinned, but it changes its shape and becomes asymmetric under electrical stimuli. This phenomenon is accompanied by strain and bound charge redistribution....
The interaction of oxygen vacancies and ferroelectric domain walls is of great scientific interest b...
Understanding and controlling the motion, stability, and equilibrium configuration of ferroelectric ...
Scanning Probe Microscopy (SPM) has emerged as an indispensable tool to probe and characterise mater...
The atomic-level response of zigzag ferroelectric domain walls (DWs) was investigated with in situ b...
The atomic-level response of zigzag ferroelectric domain walls (DWs) was investigated with in situ b...
The switching of domains in ferroelectric and multiferroic materials plays a central role in their a...
We use in situ transmission electron microscopy to directly observe, at high temporal and spatial re...
Ferroelectric nanoplates are attractive for applications in nanoelectronic devices. Defect engineeri...
A new paradigm of domain wall nanoelectronics has emerged recently, in which the domain wall in a fe...
Structure of 90{degree} ferroelectric domain boundaries in barium titanate ceramics has been studied...
Ferroelectric materials are characterized by a spontaneous polarization, which can be reoriented wit...
The interaction of oxygen vacancies and ferroelectric domain walls is of great scientific interest b...
Ferroelectric materials have been utilized in a broad range of electronic, optical, and electromecha...
AbstractAs a promising candidate for next‐generation nonvolatile memory devices, ferroelectric oxide...
We report on low-energy electron microscopy imaging of ferroelectric domains with submicron resoluti...
The interaction of oxygen vacancies and ferroelectric domain walls is of great scientific interest b...
Understanding and controlling the motion, stability, and equilibrium configuration of ferroelectric ...
Scanning Probe Microscopy (SPM) has emerged as an indispensable tool to probe and characterise mater...
The atomic-level response of zigzag ferroelectric domain walls (DWs) was investigated with in situ b...
The atomic-level response of zigzag ferroelectric domain walls (DWs) was investigated with in situ b...
The switching of domains in ferroelectric and multiferroic materials plays a central role in their a...
We use in situ transmission electron microscopy to directly observe, at high temporal and spatial re...
Ferroelectric nanoplates are attractive for applications in nanoelectronic devices. Defect engineeri...
A new paradigm of domain wall nanoelectronics has emerged recently, in which the domain wall in a fe...
Structure of 90{degree} ferroelectric domain boundaries in barium titanate ceramics has been studied...
Ferroelectric materials are characterized by a spontaneous polarization, which can be reoriented wit...
The interaction of oxygen vacancies and ferroelectric domain walls is of great scientific interest b...
Ferroelectric materials have been utilized in a broad range of electronic, optical, and electromecha...
AbstractAs a promising candidate for next‐generation nonvolatile memory devices, ferroelectric oxide...
We report on low-energy electron microscopy imaging of ferroelectric domains with submicron resoluti...
The interaction of oxygen vacancies and ferroelectric domain walls is of great scientific interest b...
Understanding and controlling the motion, stability, and equilibrium configuration of ferroelectric ...
Scanning Probe Microscopy (SPM) has emerged as an indispensable tool to probe and characterise mater...