Machine learning augmented predictive and generative model for rupture life in ferritic and austenitic steels

Machine learning augmented predictive and generative model for rupture life in ferritic and austenitic steels

Abstract The Larson–Miller parameter (LMP) offers an efficient and fast scheme to estimate the creep rupture life of alloy materials for high-temperature applications; however, poor generalizability and dependence on the constant C often result in sub-optimal performance. In this work, we show that...

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Main Authors: Osman Mamun, Madison Wenzlick, Arun Sathanur, Jeffrey Hawk, Ram Devanathan
Format: Article
Language:English
Published: Nature Publishing Group 2021-04-01
Series:npj Materials Degradation
Online Access:https://doi.org/10.1038/s41529-021-00166-5
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spelling doaj-e76d63eb1627409782b344abe8ba21472021-04-18T11:26:35ZengNature Publishing Groupnpj Materials Degradation2397-21062021-04-015111010.1038/s41529-021-00166-5Machine learning augmented predictive and generative model for rupture life in ferritic and austenitic steelsOsman Mamun0Madison Wenzlick1Arun Sathanur2Jeffrey Hawk3Ram Devanathan4Energy and Environment Directorate, Pacific Northwest National LaboratoryMaterials Performance Division, National Energy Technology LaboratoryEnergy and Environment Directorate, Pacific Northwest National LaboratoryMaterials Performance Division, National Energy Technology LaboratoryEnergy and Environment Directorate, Pacific Northwest National LaboratoryAbstract The Larson–Miller parameter (LMP) offers an efficient and fast scheme to estimate the creep rupture life of alloy materials for high-temperature applications; however, poor generalizability and dependence on the constant C often result in sub-optimal performance. In this work, we show that the direct rupture life parameterization without intermediate LMP parameterization, using a gradient boosting algorithm, can be used to train ML models for very accurate prediction of rupture life in a variety of alloys (Pearson correlation coefficient >0.9 for 9–12% Cr and >0.8 for austenitic stainless steels). In addition, the Shapley value was used to quantify feature importance, making the model interpretable by identifying the effect of various features on the model performance. Finally, a variational autoencoder-based generative model was built by conditioning on the experimental dataset to sample hypothetical synthetic candidate alloys from the learnt joint distribution not existing in both 9–12% Cr ferritic–martensitic alloys and austenitic stainless steel datasets.https://doi.org/10.1038/s41529-021-00166-5
collection DOAJ
language English
format Article
sources DOAJ
author Osman Mamun
Madison Wenzlick
Arun Sathanur
Jeffrey Hawk
Ram Devanathan
spellingShingle Osman Mamun
Madison Wenzlick
Arun Sathanur
Jeffrey Hawk
Ram Devanathan
Machine learning augmented predictive and generative model for rupture life in ferritic and austenitic steels
npj Materials Degradation
author_facet Osman Mamun
Madison Wenzlick
Arun Sathanur
Jeffrey Hawk
Ram Devanathan
author_sort Osman Mamun
title Machine learning augmented predictive and generative model for rupture life in ferritic and austenitic steels
title_short Machine learning augmented predictive and generative model for rupture life in ferritic and austenitic steels
title_full Machine learning augmented predictive and generative model for rupture life in ferritic and austenitic steels
title_fullStr Machine learning augmented predictive and generative model for rupture life in ferritic and austenitic steels
title_full_unstemmed Machine learning augmented predictive and generative model for rupture life in ferritic and austenitic steels
title_sort machine learning augmented predictive and generative model for rupture life in ferritic and austenitic steels
publisher Nature Publishing Group
series npj Materials Degradation
issn 2397-2106
publishDate 2021-04-01
description Abstract The Larson–Miller parameter (LMP) offers an efficient and fast scheme to estimate the creep rupture life of alloy materials for high-temperature applications; however, poor generalizability and dependence on the constant C often result in sub-optimal performance. In this work, we show that the direct rupture life parameterization without intermediate LMP parameterization, using a gradient boosting algorithm, can be used to train ML models for very accurate prediction of rupture life in a variety of alloys (Pearson correlation coefficient >0.9 for 9–12% Cr and >0.8 for austenitic stainless steels). In addition, the Shapley value was used to quantify feature importance, making the model interpretable by identifying the effect of various features on the model performance. Finally, a variational autoencoder-based generative model was built by conditioning on the experimental dataset to sample hypothetical synthetic candidate alloys from the learnt joint distribution not existing in both 9–12% Cr ferritic–martensitic alloys and austenitic stainless steel datasets.
url https://doi.org/10.1038/s41529-021-00166-5
work_keys_str_mv AT osmanmamun machinelearningaugmentedpredictiveandgenerativemodelforrupturelifeinferriticandausteniticsteels
AT madisonwenzlick machinelearningaugmentedpredictiveandgenerativemodelforrupturelifeinferriticandausteniticsteels
AT arunsathanur machinelearningaugmentedpredictiveandgenerativemodelforrupturelifeinferriticandausteniticsteels
AT jeffreyhawk machinelearningaugmentedpredictiveandgenerativemodelforrupturelifeinferriticandausteniticsteels
AT ramdevanathan machinelearningaugmentedpredictiveandgenerativemodelforrupturelifeinferriticandausteniticsteels
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