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Autores principales: Lim, Rachel E., Shang, Shun-Li, Chuang, Chihpin, Phan, Thien Q., Liu, Zi-Kui, Pagan, Darren C.
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2408.09447
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author Lim, Rachel E.
Shang, Shun-Li
Chuang, Chihpin
Phan, Thien Q.
Liu, Zi-Kui
Pagan, Darren C.
author_facet Lim, Rachel E.
Shang, Shun-Li
Chuang, Chihpin
Phan, Thien Q.
Liu, Zi-Kui
Pagan, Darren C.
contents X-ray diffraction is ideal for probing sub-surface state during complex or rapid thermomechanical loading of crystalline materials. However, challenges arise as the size of diffraction volumes increases due to spatial broadening and inability to deconvolute the effects of different lattice deformation mechanisms. Here, we present a novel approach to use combinations of physics-based modeling and machine learning to deconvolve thermal and mechanical elastic strains for diffraction data analysis. The method builds on a previous effort to extract thermal strain distribution information from diffraction data. The new approach is applied to extract the evolution of thermomechanical state during laser melting of an Inconel 625 wall specimen which produces significant residual stress upon cooling. A combination of heat transfer and fluid flow, elasto-plasticity, and X-ray diffraction simulations are used to generate training data for machine-learning (Gaussian Process Regression, GPR) models that map diffracted intensity distributions to underlying thermomechanical strain fields. First-principles density functional theory is used to determine accurate temperature-dependent thermal expansion and elastic stiffness used for elasto-plasticity modeling. The trained GPR models are found to be capable of deconvoluting the effects of thermal and mechanical strains, in addition to providing information about underlying strain distributions, even from complex diffraction patterns with irregularly shaped peaks.
format Preprint
id arxiv_https___arxiv_org_abs_2408_09447
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Deconvoluting Thermomechanical Effects in X-ray Diffraction Data using Machine Learning
Lim, Rachel E.
Shang, Shun-Li
Chuang, Chihpin
Phan, Thien Q.
Liu, Zi-Kui
Pagan, Darren C.
Materials Science
Computational Physics
X-ray diffraction is ideal for probing sub-surface state during complex or rapid thermomechanical loading of crystalline materials. However, challenges arise as the size of diffraction volumes increases due to spatial broadening and inability to deconvolute the effects of different lattice deformation mechanisms. Here, we present a novel approach to use combinations of physics-based modeling and machine learning to deconvolve thermal and mechanical elastic strains for diffraction data analysis. The method builds on a previous effort to extract thermal strain distribution information from diffraction data. The new approach is applied to extract the evolution of thermomechanical state during laser melting of an Inconel 625 wall specimen which produces significant residual stress upon cooling. A combination of heat transfer and fluid flow, elasto-plasticity, and X-ray diffraction simulations are used to generate training data for machine-learning (Gaussian Process Regression, GPR) models that map diffracted intensity distributions to underlying thermomechanical strain fields. First-principles density functional theory is used to determine accurate temperature-dependent thermal expansion and elastic stiffness used for elasto-plasticity modeling. The trained GPR models are found to be capable of deconvoluting the effects of thermal and mechanical strains, in addition to providing information about underlying strain distributions, even from complex diffraction patterns with irregularly shaped peaks.
title Deconvoluting Thermomechanical Effects in X-ray Diffraction Data using Machine Learning
topic Materials Science
Computational Physics
url https://arxiv.org/abs/2408.09447