A novel method for radial hydride analysis in zirconium alloys: HAPPy

A novel method for radial hydride analysis in zirconium alloys: HAPPy

Whilst substantial progress has been made in understanding the influence that hydrides have on the mechanical properties of zirconium alloys, there is currently an urgent need for a transparent, reproducible image analysis workflow for their characterisation. In this study, an open-source software p...

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Veröffentlicht in:Journal of nuclear materials 2022-02, Vol.559, p.153442, Article 153442
Hauptverfasser: Maric, Mia, Thomas, Rhys, Nunez-Iglesias, Juan, Atkinson, Michael, Bertsch, Johannes, Frankel, Philipp, Race, Christopher, Barberis, Pierre, Bourlier, Florent, Preuss, Michael, Shanthraj, Pratheek
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Sprache:eng
Schlagworte:
Algorithms
Alloys
Hydrides
Image analysis
Image processing
Mathematical analysis
Mechanical properties
Micrography
Microstructure
Photomicrographs
Workflow
Zirconium
Zirconium alloys
Zirconium base alloys
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container_end_page
container_issue
container_start_page 153442
container_title Journal of nuclear materials
container_volume 559
creator Maric, Mia
Thomas, Rhys
Nunez-Iglesias, Juan
Atkinson, Michael
Bertsch, Johannes
Frankel, Philipp
Race, Christopher
Barberis, Pierre
Bourlier, Florent
Preuss, Michael
Shanthraj, Pratheek
description Whilst substantial progress has been made in understanding the influence that hydrides have on the mechanical properties of zirconium alloys, there is currently an urgent need for a transparent, reproducible image analysis workflow for their characterisation. In this study, an open-source software package for the analysis of hydride networks, HAPPy (Hydride Analysis Package in Python), is introduced to calculate the radial hydride fraction (RHF) and mean hydride length, as well as characterising the connectivity of the microstructure both quantitatively and qualitatively. In this study, we used the Hough line transform to calculate the orientation distribution of the hydride segments within a micrograph, and its projection on to the radial direction is used to determine the RHF. The proposed methodology is validated, and its robustness is demonstrated over a wide range of microstructures. The image processing prior to analysis as well as the projection method used has been shown to have a significant influence on the calculated RHF, highlighting the need for standardized image analysis workflows to facilitate accurate comparisons and correlations across different studies in the literature. Finally, this paper introduces a new damage susceptibility parameter termed the branch length fraction, which can be used in conjunction with a path of lowest cost algorithm to visualise the most plausible crack path as well as the connectivity evolution over an entire micrograph. [Display omitted]
doi_str_mv 10.1016/j.jnucmat.2021.153442
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Finally, this paper introduces a new damage susceptibility parameter termed the branch length fraction, which can be used in conjunction with a path of lowest cost algorithm to visualise the most plausible crack path as well as the connectivity evolution over an entire micrograph. 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subjects Algorithms
Alloys
Hydrides
Image analysis
Image processing
Mathematical analysis
Mechanical properties
Micrography
Microstructure
Photomicrographs
Workflow
Zirconium
Zirconium alloys
Zirconium base alloys
title A novel method for radial hydride analysis in zirconium alloys: HAPPy
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