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6: Overlayer Structures and Surface Diffraction

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    • 6.1: Classification of Overlayer Structures
      This page explores the long-range ordering of adsorbed species on single crystal surfaces, focusing on overlayer structures and their relation to substrate atomic arrangements. It introduces fundamental concepts like the primitive unit cell and uses different face-centered cubic (fcc) surfaces for illustration.
    • 6.2: Low Energy Electron Diffraction (LEED)
      This page covers the LEED technique for analyzing crystalline surfaces, detailing its experimental setup and theoretical foundations regarding electron diffraction patterns. It also explains the relationship between real-space and reciprocal-space vectors, using a primitive (2 x 2) overlayer as a case study.
    • 6.3: Reflection High Energy Electron Diffraction (RHEED)
      This page discusses the principles of Low Energy Electron Diffraction (LEED) for analyzing surface structures with low energy electrons, noting that higher energy leads to reduced surface specificity. It introduces Reflection High Energy Electron Diffraction (RHEED) as a solution, employing grazing incidence for enhanced surface sensitivity.
    • 6.4: Examples - Surface Structures
      This page discusses the classification and determination of surface structures via Wood's and matrix notation, showcasing examples of adsorbate configurations on fcc surfaces (100, 110, 111). It addresses alloy layers and coadsorption, underlining the importance of defining adsorbate unit cells in relation to substrate unit cells. While it emphasizes the simplicity of these structures, it also notes complexities that may arise from interactions causing substrate distortions.

    This page titled 6: Overlayer Structures and Surface Diffraction is shared under a CC BY-NC-SA 4.0 license and was authored, remixed, and/or curated by Roger Nix.