Microstructural damage sensitivity prediction using spatial statistics
Microstructural damage sensitivity prediction using spatial statistics
The vast compositional space of metallic materials provides ample opportunity to design stronger, more ductile and cheaper alloys. However, the substantial complexity of deformation micro-mechanisms makes simulation-based prediction of microstructural performance exceedingly difficult. In absence of predictive tools, tedious experiments have to be conducted to screen properties. Here, we develop a purely empirical model to forecast microstructural performance in advance, bypassing these challenges. This is achieved by combining in situ deformation experiments with a novel methodology that utilizes n-point statistics and principle component analysis to extract key microstructural features. We demonstrate this approach by predicting crack nucleation in a complex dual-phase steel, achieving substantial predictive ability (84.8% of microstructures predicted to crack, actually crack), a substantial improvement upon the alternate simulation-based approaches. This significant accuracy illustrates the utility of this alternate approach and opens the door to a wide range of alloy design tools.
Cameron, B.C.
97613b73-58fa-4f8c-85a6-316c4aef7578
Tasan, C. Cem
3e2b5f4f-5e2e-4964-94d4-b53c937fc350
26 February 2019
Cameron, B.C.
97613b73-58fa-4f8c-85a6-316c4aef7578
Tasan, C. Cem
3e2b5f4f-5e2e-4964-94d4-b53c937fc350
Cameron, B.C. and Tasan, C. Cem
(2019)
Microstructural damage sensitivity prediction using spatial statistics.
Scientific Reports, 9.
(doi:10.1038/s41598-019-39315-x).
Abstract
The vast compositional space of metallic materials provides ample opportunity to design stronger, more ductile and cheaper alloys. However, the substantial complexity of deformation micro-mechanisms makes simulation-based prediction of microstructural performance exceedingly difficult. In absence of predictive tools, tedious experiments have to be conducted to screen properties. Here, we develop a purely empirical model to forecast microstructural performance in advance, bypassing these challenges. This is achieved by combining in situ deformation experiments with a novel methodology that utilizes n-point statistics and principle component analysis to extract key microstructural features. We demonstrate this approach by predicting crack nucleation in a complex dual-phase steel, achieving substantial predictive ability (84.8% of microstructures predicted to crack, actually crack), a substantial improvement upon the alternate simulation-based approaches. This significant accuracy illustrates the utility of this alternate approach and opens the door to a wide range of alloy design tools.
Text
s41598-019-39315-x
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Accepted/In Press date: 31 December 2018
Published date: 26 February 2019
Identifiers
Local EPrints ID: 476241
URI: http://eprints.soton.ac.uk/id/eprint/476241
ISSN: 2045-2322
PURE UUID: 7808fdd0-770f-4ed2-9f61-7db32367ddab
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Date deposited: 17 Apr 2023 16:38
Last modified: 17 Mar 2024 04:16
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Author:
B.C. Cameron
Author:
C. Cem Tasan
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