Non‐Destructive Tomographic Nanoscale Imaging of Ferroelectric Domain Walls

He, Jiali; Zahn, Manuel; Ushakov, Ivan N.; Richarz, Leonie; Ludacka, Ursula; Roede, Erik D.; Yan, Zewu; Bourret, Edith; Kézsmárki, István; Catalan, Gustau; Meier, Dennis

doi:10.1002/adfm.202314011

Adv Funct Materials

2024

DOI: 10.1002/adfm.202314011

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Non‐Destructive Tomographic Nanoscale Imaging of Ferroelectric Domain Walls

Jiali He,

Manuel Zahn,

Ivan N. Ushakov

et al.

Abstract: Extraordinary physical properties arise at polar interfaces in oxide materials, including the emergence of 2D electron gases, sheet‐superconductivity, and multiferroicity. A special type of polar interface is ferroelectric domain walls, where electronic reconstruction phenomena can be driven by bound charges. Great progress has been achieved in the characterization of such domain walls and, over the last decade, their potential for next‐generation nanotechnology has become clear. Established tomography techniq… Show more

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Cited by 2 publications

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Localized Flexoelectric Effect Around Ba(CuNb) Nano‐Clusters in Epitaxial BiFeO₃ Films for Enhancement of Electric and Multiferroic Properties

Song,

Hwang,

Sung

et al. 2024

Adv Funct Materials

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Room‐temperature (RT) multiferroic materials have received significant research attention for various potential applications; however, their properties are not suitable for real‐world implementation. In this study, a nano‐scale localized flexoelectric effect is introduced to enhance the RT multiferroic performance of epitaxial bismuth iron oxide (BiFeO3; BFO) thin films by embedding 10 mol% Ba(Cu1/3Nb2/3)O3 (BCN) nano‐clusters into the host BFO film, which originally has a rhombohedral crystal structure. By utilizing nano‐clustering, a large out‐of‐plane coherent strain is localized around the nano‐clusters, resulting in a highly strained tetragonality of the BFO structure; subsequently, the films exhibit peculiar types of domains and domain walls, such as nano‐scale rotational vortices and antiparallel dipole configurations. These peculiar domain structures, which originate from the localized flexoelectric effect at the nano‐scale, enable excellent ferroelectric, ferromagnetic, and RT multiferroic magnetoelectric coupling. This study reveals that the local variation in the localized flexoelectric field around nano‐clusters considerably impacts the formation of unusual domain‐wall structures. This suggests that the controlled introduction of nano‐clusters with different crystal structures is promising for achieving the desired multiferroic properties.

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Localized Flexoelectric Effect Around Ba(CuNb) Nano‐Clusters in Epitaxial BiFeO₃ Films for Enhancement of Electric and Multiferroic Properties

Song,

Hwang,

Sung

et al. 2024

Adv Funct Materials

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Depth resolution in piezoresponse force microscopy

Roeper,

Seddon,

Amber

et al. 2024

Journal of Applied Physics

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Piezoresponse force microscopy (PFM) is one of the most widespread methods for investigating and visualizing ferroelectric domain structures down to the nanometer length scale. PFM makes use of the direct coupling of the piezoelectric response to the crystal lattice, and hence, it is most often applied to spatially map the three-dimensional (3D) near-surface domain distribution of any polar or ferroic sample. Nonetheless, since most samples investigated by PFM are at least semiconducting or fully insulating, the electric ac field emerging from the conductive scanning force microscopy (SFM) tip penetrates the sample and, hence, may also couple to polar features that are deeply buried into the bulk of the sample under investigation. Thus, in the work presented here, we experimentally and theoretically explore the contrast and depth resolution capabilities of PFM, by analyzing the dependence of several key parameters. These key parameters include the depth of the buried feature, i.e., here a domain wall (DW), as well as PFM-relevant technical parameters such as the tip radius, the PFM drive voltage and frequency, and the signal-to-noise ratio. The theoretical predictions are experimentally verified using x-cut periodically poled lithium niobate single crystals that are specially prepared into wedge-shaped samples, in order to allow the buried feature, here the DW, to be “positioned” at any depth into the bulk. This inspection essentially contributes to the fundamental understanding in PFM contrast analysis and to the reconstruction of 3D domain structures down to a 1 μm-penetration depth into the sample.

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Non‐Destructive Tomographic Nanoscale Imaging of Ferroelectric Domain Walls

Cited by 2 publications

References 55 publications

Localized Flexoelectric Effect Around Ba(CuNb) Nano‐Clusters in Epitaxial BiFeO₃ Films for Enhancement of Electric and Multiferroic Properties

Localized Flexoelectric Effect Around Ba(CuNb) Nano‐Clusters in Epitaxial BiFeO₃ Films for Enhancement of Electric and Multiferroic Properties

Depth resolution in piezoresponse force microscopy

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Non‐Destructive Tomographic Nanoscale Imaging of Ferroelectric Domain Walls

Cited by 2 publications

References 55 publications

Localized Flexoelectric Effect Around Ba(CuNb) Nano‐Clusters in Epitaxial BiFeO3 Films for Enhancement of Electric and Multiferroic Properties

Localized Flexoelectric Effect Around Ba(CuNb) Nano‐Clusters in Epitaxial BiFeO3 Films for Enhancement of Electric and Multiferroic Properties

Depth resolution in piezoresponse force microscopy

Contact Info

Product

Resources

About

Localized Flexoelectric Effect Around Ba(CuNb) Nano‐Clusters in Epitaxial BiFeO₃ Films for Enhancement of Electric and Multiferroic Properties

Localized Flexoelectric Effect Around Ba(CuNb) Nano‐Clusters in Epitaxial BiFeO₃ Films for Enhancement of Electric and Multiferroic Properties