Automatic Crack Detection and Analysis for Biological Cellular Materials in X-Ray In Situ Tomography Measurements

Wu, Ziling; Yang, Ting; Deng, Zhifei; Huang, Baokun; Liu, Han; Wang, Yu; Chen, Yuan; Stoddard, Mary Caswell; Li, Ling; Zhu, Yunhui

doi:10.1007/s40192-019-00162-3

Cited by 9 publications

(5 citation statements)

References 41 publications

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“…While this proof of concept segmentation is relatively simple, it opens the opportunities for further analysis of cracks and flaws, for example by studying their internal surface areas and orientations. [ 32 ] Furthermore, the crack severity could be estimated by measuring the distance of the crack to the particle surface. After labeling and classification, the electrode could be spatially reconstructed, and the flaw distribution could be spatially localized throughout the depth of the electrode.…”

Section: Resultsmentioning

confidence: 99%

Computer‐Vision‐Based Approach to Classify and Quantify Flaws in Li‐Ion Electrodes

et al. 2022

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X‐ray computed tomography (X‐ray CT) is a non‐destructive characterization technique that in recent years has been adopted to study the microstructure of battery electrodes. However, the often manual and laborious data analysis process hinders the extraction of useful metrics that can ultimately inform the mechanisms behind cycle life degradation. This work presents a novel approach that combines two convolutional neural networks to first locate and segment each particle in a nano‐CT LiNiMnCoO2 (NMC) electrode dataset, and successively classifies each particle according to the presence of flaws or cracks within its internal structure. Metrics extracted from the computer vision segmentation are validated with respect to traditional threshold‐based segmentation, confirming that flawed particles are correctly identified as single entities. Successively, slices from each particle are analyzed by a pre‐trained classifier to detect the presence of flaws or cracks. The models are used to quantify microstructural evolution in uncycled and cycled NMC811 electrodes, as well as the number of flawed particles in a NMC622 electrode. As a proof‐of‐concept, a 3‐phase segmentation is also presented, whereby each individual flaw is segmented as a separate pixel label. It is anticipated that this analysis pipeline will be widely used in the field of battery research and beyond.

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Section: Resultsmentioning

confidence: 99%

Computer‐Vision‐Based Approach to Classify and Quantify Flaws in Li‐Ion Electrodes

et al. 2022

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“…The center of each segmented crack plane was identified by averaging all voxel locations in the crack, and the crack plane orientation was determined by the minimum principal component with principal component analysis. Further details regarding crack detection and analysis can be found in a previous work 63 . For the analysis of damage bands at the later stage of deformations, we adopted a U-net architecture in a DNN to learn the features of the fragments from the manual labeling.…”

Section: Methodsmentioning

confidence: 99%

High strength and damage-tolerance in echinoderm stereom as a natural bicontinuous ceramic cellular solid

Yang

Jia

et al. 2022

Nat Commun

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Due to their low damage tolerance, engineering ceramic foams are often limited to non-structural usages. In this work, we report that stereom, a bioceramic cellular solid (relative density, 0.2–0.4) commonly found in the mineralized skeletal elements of echinoderms (e.g., sea urchin spines), achieves simultaneous high relative strength which approaches the Suquet bound and remarkable energy absorption capability (ca. 17.7 kJ kg−1) through its unique bicontinuous open-cell foam-like microstructure. The high strength is due to the ultra-low stress concentrations within the stereom during loading, resulted from their defect-free cellular morphologies with near-constant surface mean curvatures and negative Gaussian curvatures. Furthermore, the combination of bending-induced microfracture of branches and subsequent local jamming of fractured fragments facilitated by small throat openings in stereom leads to the progressive formation and growth of damage bands with significant microscopic densification of fragments, and consequently, contributes to stereom’s exceptionally high damage tolerance.

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“…With binary_crossentropy, we can interpret the probability of crack in each pixel from 0 to 1 as the probability of crack on different positions. [48][49][50] Through this approach, the crack prediction problem become a multiclassification problem.…”

Section: Machine-learning Modelmentioning

confidence: 99%

Using Deep Learning to Predict Fracture Patterns in Crystalline Solids

Hsu

Buehler

2020

Matter

117

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Automatic Crack Detection and Analysis for Biological Cellular Materials in X-Ray In Situ Tomography Measurements

Cited by 9 publications

References 41 publications

Computer‐Vision‐Based Approach to Classify and Quantify Flaws in Li‐Ion Electrodes

Computer‐Vision‐Based Approach to Classify and Quantify Flaws in Li‐Ion Electrodes

High strength and damage-tolerance in echinoderm stereom as a natural bicontinuous ceramic cellular solid

Using Deep Learning to Predict Fracture Patterns in Crystalline Solids

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