A new paradigm in electron microscopy: Automated microstructure analysis utilizing a dynamic segmentation convolutional neutral network

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Abstract

Over the past half century, the transmission electron microscope enabled insight into the fundamental arrangements and structures of materials. State-of-the-art electron microscopes can acquire large image datasets across multiple imaging modalities. However, the manual annotation process for feature or defect quantification may not be feasible with the modern microscope. Convolutional neural networks emerged to characterize individual microstructural features from an image in a cost-effective, consistent manner. However, many of these neural network approaches rely on thousands to hundreds of thousands of manual annotations of each feature type across hundreds of images to train the network for adequate performance. This work focused on the development and application of a pixel-wise defect detection machine-learning dynamic segmentation convolutional neural network with associated automated acquisition and postprocessing to identify microstructural features rapidly and quantitatively from a small initial dataset incorporating multiple imaging modes. The approach was demonstrated for characterization of superalloy 718 from both single image acquisition on multiple detectors to in-situ evolution captured with a single detector on a standard desktop computer to demonstrate the low barrier to entry required for widespread adoption. Pixel-by-pixel class identification was excellent with strong identification of chemically distinct phases, structurally distinct phases, and defect structures, thus demonstrating the new paradigm of machine learning-assisted characterization.

Original languageEnglish
Article number100468
JournalMaterials Today Advances
Volume21
DOIs
StatePublished - Mar 2024
Externally publishedYes

Funding

This research was sponsored in part by the Laboratory Directed Research and Development Program of Oak Ridge National Laboratory ( ORNL ), managed by UT- Battelle , LLC, for the US Department of Energy (DOE). This research was supported by the Transformational Challenge Reactor and Advanced Materials and Manufacturing Technologies programs supported by the DOE Office of Nuclear Energy . This work was supported in part by the DOE Office of Nuclear Energy under DOE Idaho Operations Office Contract DE-AC07- 051D14517 as part of a Nuclear Science User Facilities experiment for access to the in-situ ion irradiation capabilities at the Michigan Ion Beam Laboratory. Ty Austin's contributions are based on work supported under a DOE Office of Nuclear Energy Integrated University Program Graduate Fellowship. STEM characterization was performed in the Low Activation Materials Development and Analysis laboratory at ORNL. Additionally, the authors acknowledge Keith Carver for operating the Concept X-Line 2000R to produce the additively manufactured superalloy 718, Tom Geer, Tim Lach and Gavin Mattingly for sample preparation, Kai Sun for helping to collect the in-situ ion irradiation images, and Clay Leach for developing the module to enable video analysis. This research was sponsored in part by the Laboratory Directed Research and Development Program of Oak Ridge National Laboratory (ORNL), managed by UT-Battelle, LLC, for the US Department of Energy (DOE). This research was supported by the Transformational Challenge Reactor and Advanced Materials and Manufacturing Technologies programs supported by the DOE Office of Nuclear Energy. This work was supported in part by the DOE Office of Nuclear Energy under DOE Idaho Operations Office Contract DE-AC07- 051D14517 as part of a Nuclear Science User Facilities experiment for access to the in-situ ion irradiation capabilities at the Michigan Ion Beam Laboratory. Ty Austin's contributions are based on work supported under a DOE Office of Nuclear Energy Integrated University Program Graduate Fellowship. STEM characterization was performed in the Low Activation Materials Development and Analysis laboratory at ORNL. Additionally, the authors acknowledge Keith Carver for operating the Concept X-Line 2000R to produce the additively manufactured superalloy 718, Tom Geer, Tim Lach and Gavin Mattingly for sample preparation, Kai Sun for helping to collect the in-situ ion irradiation images, and Clay Leach for developing the module to enable video analysis.

FundersFunder number
DOE Office of Nuclear Energy Integrated University
Keith Carver for operating the Concept X-Line 2000R718
U.S. Department of Energy
Office of Nuclear EnergyDE-AC07- 051D14517
Oak Ridge National Laboratory
UT-Battelle

    Keywords

    • Automation
    • Machine learning
    • Microstructure
    • TEM

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