Location via proxy:   [ UP ]  
[Report a bug]   [Manage cookies]                
  • Open Access

Buried moiré supercells through SrTiO3 nanolayer relaxation

Max Burian, Bill Francesco Pedrini, Nazaret Ortiz Hernandez, Hiroki Ueda, C. A. F. Vaz, Marco Caputo, Milan Radovic, and Urs Staub
Phys. Rev. Research 3, 013225 – Published 9 March 2021
PDFHTMLExport Citation
Abstract
Authors
Article Text
  • ACKNOWLEDGMENTS
  • APPENDICES
    • References

    Abstract

    We identified a highly ordered moiré lattice at the buried SrTiO3 (STO)-(La,Sr)(Al,Ta)-oxide (LSAT) interface by high-resolution x-ray diffraction reciprocal space mapping. We found long-ranged ordered supercells of 106/107 unit cells of unstrained STO-LSAT caused by complete lattice relaxation through high-temperature annealing. Transmission electron microscopy images show that this periodicity is based on line dislocations at the interface region. The presence of such ordered superstructures in such widely used complex oxides sets the ideal conditions for moiré-tuned interfacial electronic modifications and ferroelectric supercrystallinity, opening the possibility for interface functionalities and impacting findings on vortex structured multilayers systems.

    • Figure
    • Figure
    • Figure
    • Figure
    • Figure
    • Figure
    • Figure
    2 More
    • Received 11 May 2020
    • Revised 28 October 2020
    • Accepted 9 February 2021

    DOI:https://doi.org/10.1103/PhysRevResearch.3.013225

    Published by the American Physical Society under the terms of the Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.

    Published by the American Physical Society

    Physics Subject Headings (PhySH)

    1. Research Areas
    Crystal phenomenaFerroelectricitySurface instabilities
    1. Physical Systems
    Interfaces
    Condensed Matter, Materials & Applied Physics

    Authors & Affiliations

    Max Burian*, Bill Francesco Pedrini, Nazaret Ortiz Hernandez, Hiroki Ueda, C. A. F. Vaz, Marco Caputo, Milan Radovic, and Urs Staub

    • Swiss Light Source, Paul Scherrer Institute, 5232 Villigen PSI, Switzerland

    • *max.burian@psi.ch
    • urs.staub@psi.ch

    Article Text

    Click to Expand

    References

    Click to Expand
    Issue

    Vol. 3, Iss. 1 — March - May 2021

    Subject Areas
    Reuse & Permissions
    Author publication services for translation and copyediting assistance advertisement

    Authorization Required

    Log In
    Other Options
    ×

    Images

    • Figure 1
      Figure 1

      Slices through the reciprocal space volume (RSV) obtained by x-ray diffraction (XRD) at the (2, 0, L) family peaks. The reciprocal space distance between substrate and surface layer peak increases linearly with L diffraction order, yielding an out-of-plane lattice difference of 1.07±0.10%. The scattering intensity is scaled logarithmically according to the color bar.

      Reuse & Permissions
    • Figure 2
      Figure 2

      (a) Out-of-plane and (b) in-plane sliced projections of the reciprocal space volume (RSV) obtained by x-ray scattering on the (2, K, 4) family peaks, showing a commensurate relation between atomic lattice reflections and the superstructure scattering rods. Black dashed lines mark the center of the Bragg reflection in the SrTiO3 (STO) reference frame. The scattering intensity is scaled logarithmically according to the color bar. (c) The intensity of two-dimensional (2D) Fourier transform of a theoretical 106/107 moiré lattice reproduces the same scattering behavior if an induced phase shift is considered.

      Reuse & Permissions
    • Figure 3
      Figure 3

      (a) Structural illustration of the SrTiO3(STO)(LaAlO3)0.3(Sr2TaAlO6)0.7(LSAT) interface due to lattice relaxation, shown along the STO (100) direction. Starting from perfect overlap of the corresponding unit cells (uc; see black dashed area at ucSTO=0), the local mismatch of the interfacial oxygen atoms increases until it is maximal at half the moiré periodicity (see red dashed area at ucSTO=53). Eventually, the LSAT and STO unit cells overlap again (see black dashed area at ucSTO=106), effectively forming a two-dimensional (2D) 106/107 moiré pattern. (b) High resolution transmission electron microscopy (HRTEM) images of the sample cross-section, showing a highly ordered arrangement (mean distance of 44.6 nm) of dislocations that form where the local mismatch is largest.

      Reuse & Permissions
    • Figure 4
      Figure 4

      (a) Atomic force microscopy (AFM) image of the SrTiO3 (STO) surface after annealing, showing a common lateral disordered arrangement of islands. (b) Reciprocal space image of the surface morphology obtained via two-dimensional (2D) fast Fourier transform (FFT) (using Hanning window function) of the AFM image shown in (a). The radial-symmetric intensity distribution confirms no preferred alignment direction of the surface features. (c) Average of 20 radial cuts together with a Gaussian fit to quantify the mean correlation length.

      Reuse & Permissions
    • Figure 5
      Figure 5

      Line cuts through the (2, 0, 2) reciprocal space volume (RSV; see Fig. 2) along (a) (0, 0, l), (b) (h, 0, 0), and (c) (0, k, 0). The out-of-plane fringe pattern in (a) was fitted (blue line) to obtain the film thickness of 33 ± 2 nm. In (b) and (c), along both directions, clear satellite peaks around the central (2, 0, 2) reflection are evident.

      Reuse & Permissions
    • Figure 6
      Figure 6

      Gaussian fits of the first satellite peaks seen in the horizontal line cuts along (a) (h, 0, 0) and (b) (0, k, 0), as shown in Figs. 5 and 5.

      Reuse & Permissions
    • Figure 7
      Figure 7

      (a) Real-space interference matrix IAB illustrating occurrence of a moiré lattice from two exemplary 910 base lattices, as shown in green and blue. After sufficient unit cell repetitions, the two lattice base points overlap, causing an increase in the scattering length density (SLD) in our model (lattice overlap points marked by orange arrows). These overlap points reoccur in a square symmetry, which constitutes the “moiré lattice” (see red box). (b) and (c) Intensity of the fast Fourier transforms (FFTs) of the interference matrix IAB. (b) FFT where all IAB matrix elements have no complex terms. Only the two reflection families stemming from the base lattices A and B (green and blue) are visible. (c) FFT where an arbitrary complex constant has been added at the overlap points shown in (a). In addition to the two base lattice reflections (green and blue), higher order contributions from the interference superstructure appear. These moiré lattice reflections are consistent with experimental observations (see Fig. 2).

      Reuse & Permissions
    • Figure 8
      Figure 8

      Results of the three-dimensional (3D) model calculations, showing the intensity of the fast Fourier transforms (FFTs) that yield reciprocal space volumes (RSVs) along the (a) out-of-plane and (b) in-plane direction. (c) Illustrative sketches of the underlying geometries. The left column shows results from two lattices of different sizes and no out-of-plane corrugation, yielding only Bragg-like reflections that correspond to the two unit cell parameters. The middle column shows results from two lattices of different sizes and 10% out-of-plane corrugation, and the right column shows results from two lattices of different sizes and 10% in-plane atomic displacements. Here, a strong superstructure scattering contribution is observed, confirming both in- and out-of-plane corrugation as a cause for the experimentally observed scattering features.

      Reuse & Permissions
    • Figure 9
      Figure 9

      (a) In-plane and (b) out-of-plane cuts through the reciprocal space volume (RSV) of the (0, 0, 2) reflection of SrTiO3 (STO)- NdGaO3 (NGO) sample system. Also, in this case, we observe the same moiré superstructure scattering motif as in the STO(LaAlO3)0.3(Sr2TaAlO6)0.7(LSAT) system but with a spacing of Δh=0.0106, relating to a real-space d spacing of 36.8 nm. (c) High resolution transmission electron microscopy (HRTEM) images of a sample cross-section, showing the sample lattice dislocation pattern at the interface as for the STO-LSAT system [see Fig. 3] but with a periodicity of 38.2 ± 1.8 nm.

      Reuse & Permissions
    ×

    Sign up to receive regular email alerts from Physical Review Research

    Reuse & Permissions

    It is not necessary to obtain permission to reuse this article or its components as it is available under the terms of the Creative Commons Attribution 4.0 International license. This license permits unrestricted use, distribution, and reproduction in any medium, provided attribution to the author(s) and the published article's title, journal citation, and DOI are maintained. Please note that some figures may have been included with permission from other third parties. It is your responsibility to obtain the proper permission from the rights holder directly for these figures.

    ×

    Log In

    Cancel
    ×

    Search

    Article Lookup

    Paste a citation or DOI
    Enter a citation
    ×