Correlative imaging of ferroelectric domain walls

Gaponenko, Iaroslav; Cherifi‐Hertel, Salia; Acevedo-Salas, Ulises; Bassiri‐Gharb, Nazanin; Paruch, Patrycja

doi:10.1038/s41598-021-04166-y

Cited by 7 publications

(7 citation statements)

References 39 publications

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“…[12] Similarly, machine learning methods have boosted the sensitivity of second-harmonic generation microscopy (SHG) to obtain phase information in reference-free experiments, [13] provide automatic cancer diagnosis in breast tissues using high-throughput SHG polarimetry studies, [14] or achieve correlative imaging at the nanoscale by combining SHG polarimetry and scanning probe microscopy. [15] This study demonstrates the high potential of laterally-resolved SHG polarimetry assisted by machine learning methods to investigate the ferroic order through the analysis of the domain structure of Germanium Telluride (GeTe), a high-T c non-oxide ferroelectric. Such Rashba-type ferroelectrics have recently attracted great attention owing to their potential technological applications based on the ferroelectric control of the Rashba-type spin-orbit coupling.…”

Section: Introductionmentioning

confidence: 93%

“…In particular, clustering methods are highly suited for the identification of groups with distinct properties in a given data set, based on a concept of similarity between elements within each cluster. [15,30,46,47] In the present analysis, clustering was performed through K-means clustering in order to segment the SHG datasets into regions of interest with distinct behaviors corresponding to ferroelectric domain variants. Euclidean distance criterion is used to segment the data set into spatially indexed clusters, with centroids encoding the differing mean behaviors within each cluster.…”

Section: Deriving the Domain Structure Using The K-means Clustering M...mentioning

confidence: 99%

“…[ 12 ] Similarly, machine learning methods have boosted the sensitivity of second‐harmonic generation microscopy (SHG) to obtain phase information in reference‐free experiments, [ 13 ] provide automatic cancer diagnosis in breast tissues using high‐throughput SHG polarimetry studies, [ 14 ] or achieve correlative imaging at the nanoscale by combining SHG polarimetry and scanning probe microscopy. [ 15 ]…”

Section: Introductionmentioning

confidence: 99%

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Automatic Ferroelectric Domain Pattern Recognition Based on the Analysis of Localized Nonlinear Optical Responses Assisted by Machine Learning

Croes

Gaponenko

Voulot

et al. 2022

Advanced Physics Research

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Second-harmonic generation (SHG) is a nonlinear optical method allowing the study of the local structure, symmetry, and ferroic order in noncentrosymmetric materials such as ferroelectrics. The combination of SHG microscopy with local polarization analysis is particularly efficient for deriving the local polarization orientation. This, however, entails the use of tedious and time-consuming modeling methods of nonlinear optical emission. Moreover, extracting the complex domain structures often observed in thin films requires a pixel-by-pixel analysis and the fitting of numerous polar plots to ascribe a polarization angle to each pixel. Here, the domain structure of GeTe films is studied using SHG polarimetry assisted by machine learning. The method is applied to two film thicknesses: A thick film containing large domains visible in SHG images, and a thin film in which the domains' size is below the SHG resolution limit. Machine learning-assisted methods show that both samples exhibit four domain variants of the same type. This result is confirmed in the case of the thick film, both by the manual pixel-by-pixel analysis and by using piezoresponse force microscopy. The proposed approach foreshows new prospects for optical studies by enabling enhanced sensitivity and high throughput analysis.

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Section: Introductionmentioning

confidence: 93%

Section: Deriving the Domain Structure Using The K-means Clustering M...mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Automatic Ferroelectric Domain Pattern Recognition Based on the Analysis of Localized Nonlinear Optical Responses Assisted by Machine Learning

Croes

Gaponenko

Voulot

et al. 2022

Advanced Physics Research

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“…[25] Thus, in the last two decades, PFM has become an indispensable tool in observing ferroelectric properties owing to its ease of operation and nanoscale resolution. [26][27][28][29][30][31] Many studies on bulk ferroelectrics seek to determine their 3D domain structure through the domain control of local surfaces and imaging of the polarization distribution. In the case of nanoscale ferroelectrics, the growth and structure of exotic domains have been observed in BaTiO 3 , Pb(Zr 0.2 Ti 0.8 )O 3 , and BiFeO 3 films and nanodot arrays.…”

Section: Introductionmentioning

confidence: 99%

Center‐Type Topological Domain States in Ferroelectric Nanodots Tailored from Thin Films

Zhang

et al. 2023

Physica Rapid Research Ltrs

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This article reports on using atomic force microscopy to investigate the structure and switching of ferroelectric domains on nanodot arrays. High‐density arrays of epitaxial discrete nanodots are fabricated by the template‐assisted tailoring of thin films. Furthermore, the measurement of the vectorial polarization distribution and switching of domains is conducted, which helps identify four topological domain states. In addition to convergent and divergent domain states with upward and downward polarization, double‐center and triple‐center domains are identified. Thus, the study shows the formation mechanisms for these topological domain states using the accumulation of mobile charges on the interface and the strain gradient arising from the tailoring of thin films into nanodots. The properties of these exotic multicenter topological domain states provide the opportunity to further study their potential application in high‐density storage devices.

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“…To address these limitations, machine learning (ML) has proven itself a valuable tool for facilitating interpretation of multidimensional datasets, including those generated by resonant SPM methods like RPFM. [27,[31][32][33][34][35][36][37][38] Although less susceptible to user bias, ML approaches are still mathematical algorithms by definition, agnostic of the underlying physical and chemical phenomena. Hence, their outputs are not necessarily representative of the physical response of the sample.…”

Section: Introductionmentioning

confidence: 99%

Mask or Enhance: Data Curation Aiding the Discovery of Piezoresponse Force Microscopy Contributors

Ligonde

Williams

Gaponenko

et al. 2023

Advanced Physics Research

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Piezoresponse force microscopy (PFM) is routinely used to probe the nanoscale electromechanical response of ferroelectric and piezoelectric materials. However, many challenges remain in the interpretation of the recovered signal. Specifically, many non‐ferroelectric contributions affect the measured response, ranging from electrostatics, to charge injection and trapping, and topographic cross‐talk. Recently, machine learning (ML) has been utilized to identify multiple contributors within complex data systems, such as PFM response. A substantial advancement in ML approaches for PFM techniques is offered by dimensional stacking, enabling encoding of physical and/or chemical correlations within the materials' response across different data dimensions spanning varying ranges. However, dimensional stacking requires appropriate scaling for each dimension (before ML analysis) to minimize undesired information loss. Here, the impact of clustering globally and locally scaled parameters in polarization switching experiments via resonant PFM (RPFM) are discussed. Specifically, dimensional stacking of scaled parameters can mask or enhance ferroelectric and non‐ferroelectric behaviors, and aid identification of various physical phenomena contributing to the measured RPFM response. This study highlights the importance of data curation for ML, and its role in identifying signal contributors to scanning probe microscopy (SPM)‐based techniques with multidimensional data, such as resonant and/or spectroscopic SPM.

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Correlative imaging of ferroelectric domain walls

Cited by 7 publications

References 39 publications

Automatic Ferroelectric Domain Pattern Recognition Based on the Analysis of Localized Nonlinear Optical Responses Assisted by Machine Learning

Automatic Ferroelectric Domain Pattern Recognition Based on the Analysis of Localized Nonlinear Optical Responses Assisted by Machine Learning

Center‐Type Topological Domain States in Ferroelectric Nanodots Tailored from Thin Films

Mask or Enhance: Data Curation Aiding the Discovery of Piezoresponse Force Microscopy Contributors

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