Coupling physics in machine learning to predict properties of high-temperatures alloys

Peng, Jianfei; Yamamoto, Yukinori; Hawk, Jeffrey A.; Shin, Dongwon

doi:10.1038/s41524-020-00407-2

Cited by 51 publications

(27 citation statements)

References 45 publications

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“…From the table, it is evident that the model is not overfitting the data as the training and testing performance are quite similar. However, considering the performance of the state-of-the-art model ( > 0.95) for yield stress prediction reported in the literature 33 for a similar FMA dataset and the high variance of the , this performance is deemed as unsatisfactory for accurate prediction of rupture strength. It is worth noting that in that study, in addition to the chemical composition and processing parameters, synthetic alloy features generated using CALPHAD were incorporated to capture microstructural and phase transformation related information.…”

Section: Resultsmentioning

confidence: 99%

A machine learning aided interpretable model for rupture strength prediction in Fe-based martensitic and austenitic alloys

Mamun

Wenzlick

Hawk

et al. 2021

Sci Rep

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The class of 9–12% Cr ferritic-martensitic alloys (FMA) and austenitic stainless steels have received considerable attention due to their numerous applications in high temperature power generation industries. To design high strength steels with prolonged service life requires a thorough understanding of the long-term properties, e.g., creep rupture strength, rupture life, etc., as a function of the chemical composition and processing parameters that govern the microstructural characteristics. In this article, the creep rupture strength of both 9–12% Cr FMA and austenitic stainless steel has been parameterized using curated experimental datasets with a gradient boosting machine. The trained model has been cross validated against unseen test data and achieved high predictive performance in terms of correlation coefficient ($$R^{2} > 0.98 $$ R 2 > 0.98 for 9–12% Cr FMA and $$R^{2} > 0.95 $$ R 2 > 0.95 for austenitic stainless steel) thus bypassing the need for additional comprehensive tensile test campaigns or physical theoretical calculations. Furthermore, the feature importance has been computed using the Shapley value analysis to understand the complex interplay of different features.

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Section: Resultsmentioning

confidence: 99%

A machine learning aided interpretable model for rupture strength prediction in Fe-based martensitic and austenitic alloys

Mamun

Wenzlick

Hawk

et al. 2021

Sci Rep

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“…Pattern detection in the research of glassy matter is generally regarded as a supervised learning process where appropriate machine learning features (and/or regressors) are trained based on a large set of atom-wise dynamical measures (atomic trajectories, mobility, or rearrangements) and corresponding local structural information (e.g., average pair correlation function, coordination number, bond orientation etc.) [ 17 , 115 , 116 , 117 ]. The concept was largely put forward in a series of important papers applying machine learning to describe the interplay between structure and dynamics in several glass formers as well as polycrystals [ 42 ].…”

Section: Informatics In Deformation Experiments and Simulationsmentioning

confidence: 99%

Materials Informatics for Mechanical Deformation: A Review of Applications and Challenges

et al. 2021

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In the design and development of novel materials that have excellent mechanical properties, classification and regression methods have been diversely used across mechanical deformation simulations or experiments. The use of materials informatics methods on large data that originate in experiments or/and multiscale modeling simulations may accelerate materials’ discovery or develop new understanding of materials’ behavior. In this fast-growing field, we focus on reviewing advances at the intersection of data science with mechanical deformation simulations and experiments, with a particular focus on studies of metals and alloys. We discuss examples of applications, as well as identify challenges and prospects.

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“…The MIC method can identify the strength of both linear and nonlinear relationships, but only the magnitude without a sign. Both approaches are expected to provide insights into the correlation between input features and k p from differing statistical aspects, which may inspire alloy design experts to generate alloy hypotheses 23,26 . Moreover, correlation analysis can facilitate the training of high-fidelity ML models using highly ranked features.…”

Section: Correlation Analysesmentioning

confidence: 99%

“…Recently, data analytics approaches have been successfully applied to predict the mechanical properties of multi-component high-temperature alloys 18,[22][23][24][25][26][27] . While high-temperature oxidation also has scientific and practical importance, to the best of the authors' knowledge, very limited effort has been made to predict the oxidation kinetics of complex multi-component alloys by ML.…”

Section: Introductionmentioning

confidence: 99%

“…From a statistical perspective, a good agreement between the predicted and experimental k p was achieved. However, their dataset was collected from multiple literature sources; thus, the data may exhibit mixed oxidation mechanisms due to the difference in experimental protocols (i.e., atmospheres and isothermal or cyclic exposures) 26 . Moreover, their work focused only on building predictive models without analyzing the relationship between input features and k p .…”

Section: Introductionmentioning

confidence: 99%

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Data analytics approach to predict high-temperature cyclic oxidation kinetics of NiCr-based Alloys

et al. 2021

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Although of practical importance, there is no established modeling framework to accurately predict high-temperature cyclic oxidation kinetics of multi-component alloys due to the inherent complexity. We present a data analytics approach to predict the oxidation rate constant of NiCr-based alloys as a function of composition and temperature with a highly consistent and well-curated experimental dataset. Two characteristic oxidation models, i.e., a simple parabolic law and a statistical cyclic oxidation model, have been chosen to numerically represent the high-temperature oxidation kinetics of commercial and model NiCr-based alloys. We have successfully trained machine learning (ML) models using highly ranked key input features identified by correlation analysis to accurately predict experimental parabolic rate constants (kp). This study demonstrates the potential of ML approaches to predict oxidation kinetics of alloys over wide composition and temperature ranges. This approach can also serve as a basis for introducing more physically meaningful ML input features to predict the comprehensive cyclic oxidation behavior of multi-component high-temperature alloys with proper constraints based on the known underlying mechanisms.

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Coupling physics in machine learning to predict properties of high-temperatures alloys

Cited by 51 publications

References 45 publications

A machine learning aided interpretable model for rupture strength prediction in Fe-based martensitic and austenitic alloys

A machine learning aided interpretable model for rupture strength prediction in Fe-based martensitic and austenitic alloys

Materials Informatics for Mechanical Deformation: A Review of Applications and Challenges

Data analytics approach to predict high-temperature cyclic oxidation kinetics of NiCr-based Alloys

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