Thickness Profiling of Electron Transparent Aluminium Alloy Foil using Convergent Beam Electron Diffraction

Artenis Bendo; Masoud Moshtaghi; Matthew Smith; Zelong Jin; Yida Xiong; Kenji Matsuda; Xiaorong Zhou

Thickness Profiling of Electron Transparent Aluminium Alloy Foil using Convergent Beam Electron Diffraction

Artenis Bendo, Masoud Moshtaghi, Matthew Smith, Zelong Jin, Yida Xiong, Kenji Matsuda, Xiaorong Zhou

Research output: Contribution to journal › Article › peer-review

Abstract

Convergent beam electron diffraction (CBED) was used to profile the thickness of aluminium alloys foils prepared by using the twinjet electropolishing method. The two-beam CBED condition was obtained by exciting the {200} and {111} aluminium diffracted g-vector. The aluminium alloy foil thicknesses were calculated at different distances from the sample hole edge. In areas where only one Kossel-Mӧllenstedt (K-M) minima fringe was obtained, the thickness was determined by matching the experimental with simulated convergent beam diffraction pattens. In areas far away from the sample edge, the thickness of foils was high enough to generate at least two (K-M) minima fringes, required for linear regression fitting.

Original language	English
Journal	Journal of Microscopy
Publication status	Accepted/In press - 25 Jul 2022

Future Liquid Metal Engineering Hub
Zhou, X. (PI)
1/11/15 → 31/10/23
Project: Research

Cite this

@article{c5262034816a42e48c7b0e1db9cd32c9,

title = "Thickness Profiling of Electron Transparent Aluminium Alloy Foil using Convergent Beam Electron Diffraction",

abstract = "Convergent beam electron diffraction (CBED) was used to profile the thickness of aluminium alloys foils prepared by using the twinjet electropolishing method. The two-beam CBED condition was obtained by exciting the {200} and {111} aluminium diffracted g-vector. The aluminium alloy foil thicknesses were calculated at different distances from the sample hole edge. In areas where only one Kossel-Mӧllenstedt (K-M) minima fringe was obtained, the thickness was determined by matching the experimental with simulated convergent beam diffraction pattens. In areas far away from the sample edge, the thickness of foils was high enough to generate at least two (K-M) minima fringes, required for linear regression fitting. ",

author = "Artenis Bendo and Masoud Moshtaghi and Matthew Smith and Zelong Jin and Yida Xiong and Kenji Matsuda and Xiaorong Zhou",

year = "2022",

month = jul,

day = "25",

language = "English",

journal = "Journal of Microscopy",

issn = "0022-2720",

publisher = "John Wiley & Sons Ltd",

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TY - JOUR

T1 - Thickness Profiling of Electron Transparent Aluminium Alloy Foil using Convergent Beam Electron Diffraction

AU - Bendo, Artenis

AU - Moshtaghi, Masoud

AU - Smith, Matthew

AU - Jin, Zelong

AU - Xiong, Yida

AU - Matsuda, Kenji

AU - Zhou, Xiaorong

PY - 2022/7/25

Y1 - 2022/7/25

N2 - Convergent beam electron diffraction (CBED) was used to profile the thickness of aluminium alloys foils prepared by using the twinjet electropolishing method. The two-beam CBED condition was obtained by exciting the {200} and {111} aluminium diffracted g-vector. The aluminium alloy foil thicknesses were calculated at different distances from the sample hole edge. In areas where only one Kossel-Mӧllenstedt (K-M) minima fringe was obtained, the thickness was determined by matching the experimental with simulated convergent beam diffraction pattens. In areas far away from the sample edge, the thickness of foils was high enough to generate at least two (K-M) minima fringes, required for linear regression fitting.

AB - Convergent beam electron diffraction (CBED) was used to profile the thickness of aluminium alloys foils prepared by using the twinjet electropolishing method. The two-beam CBED condition was obtained by exciting the {200} and {111} aluminium diffracted g-vector. The aluminium alloy foil thicknesses were calculated at different distances from the sample hole edge. In areas where only one Kossel-Mӧllenstedt (K-M) minima fringe was obtained, the thickness was determined by matching the experimental with simulated convergent beam diffraction pattens. In areas far away from the sample edge, the thickness of foils was high enough to generate at least two (K-M) minima fringes, required for linear regression fitting.

M3 - Article

SN - 0022-2720

JO - Journal of Microscopy

JF - Journal of Microscopy

ER -

Thickness Profiling of Electron Transparent Aluminium Alloy Foil using Convergent Beam Electron Diffraction

Abstract

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Future Liquid Metal Engineering Hub

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