Towards physical insights on microstructural damage nucleation from data analytics
Towards physical insights on microstructural damage nucleation from data analytics
Variations in the chemical composition or thermomechanical processing of metallic materials result in a vast landscape of possible microstructural morphologies. While this creates ample opportunities for alloys with improved mechanical performance, the design process is challenging due to the morphological complexity and the range of deformation micro-mechanisms involved. Empirically based statistical approaches are well suited to address some of these challenges. Previously, a model based on n-point statistics and principal component analysis was successfully used for predicting damage nucleation based on the microstructural morphology of dual-phase steels. Here, we give an in-depth exploration and analysis of such algorithms as applied to experimental data. First, we investigate model architecture by implementing and testing over 1000 model variants. This leads to improved predictive ability and several alternate architectures including one with a Fourier transformation instead of a n-point statistics transformation. Second, we analyze the noise, resolution and data quantity impact to give guidelines on the necessary data required to train a predictive model. Third, we investigate which morphological features are utilized by the model to make predictions by inputting artificially-constructed microstructures, inverting the model, examination of the basis image, and variation of model hyperparameters. It is found that grain boundary fluctuations less than 1 μm are correlated to damage nucleation. This is consistent with observations in the literature on the effect of grain size and interconnected martensite regions on damage nucleation. Furthermore, it may give insights into the superior mechanical properties of alloys with bimodal grain size distributions. This demonstrates a unique approach of elucidating morphological effects from a single alloy by exploiting microstructural heterogeneity. It may be applied to other microstructures as well.
Cameron, Ben
97613b73-58fa-4f8c-85a6-316c4aef7578
Tasan, C. Cem
3e2b5f4f-5e2e-4964-94d4-b53c937fc350
Cameron, Ben
97613b73-58fa-4f8c-85a6-316c4aef7578
Tasan, C. Cem
3e2b5f4f-5e2e-4964-94d4-b53c937fc350
Cameron, Ben and Tasan, C. Cem
(2021)
Towards physical insights on microstructural damage nucleation from data analytics.
Computational Materials Science, [110627].
(doi:10.1016/j.commatsci.2021.110627).
Abstract
Variations in the chemical composition or thermomechanical processing of metallic materials result in a vast landscape of possible microstructural morphologies. While this creates ample opportunities for alloys with improved mechanical performance, the design process is challenging due to the morphological complexity and the range of deformation micro-mechanisms involved. Empirically based statistical approaches are well suited to address some of these challenges. Previously, a model based on n-point statistics and principal component analysis was successfully used for predicting damage nucleation based on the microstructural morphology of dual-phase steels. Here, we give an in-depth exploration and analysis of such algorithms as applied to experimental data. First, we investigate model architecture by implementing and testing over 1000 model variants. This leads to improved predictive ability and several alternate architectures including one with a Fourier transformation instead of a n-point statistics transformation. Second, we analyze the noise, resolution and data quantity impact to give guidelines on the necessary data required to train a predictive model. Third, we investigate which morphological features are utilized by the model to make predictions by inputting artificially-constructed microstructures, inverting the model, examination of the basis image, and variation of model hyperparameters. It is found that grain boundary fluctuations less than 1 μm are correlated to damage nucleation. This is consistent with observations in the literature on the effect of grain size and interconnected martensite regions on damage nucleation. Furthermore, it may give insights into the superior mechanical properties of alloys with bimodal grain size distributions. This demonstrates a unique approach of elucidating morphological effects from a single alloy by exploiting microstructural heterogeneity. It may be applied to other microstructures as well.
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Accepted/In Press date: 31 May 2021
e-pub ahead of print date: 18 November 2021
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Local EPrints ID: 476192
URI: http://eprints.soton.ac.uk/id/eprint/476192
ISSN: 0927-0256
PURE UUID: acbc03de-3c05-4492-a1e1-f2a765959349
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Date deposited: 13 Apr 2023 17:02
Last modified: 17 Mar 2024 04:16
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Author:
Ben Cameron
Author:
C. Cem Tasan
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