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

Mamun, Osman; Wenzlick, Madison; Hawk, Jeffrey A.; Devanathan, Ram

doi:10.1038/s41598-021-83694-z

Cited by 23 publications

(11 citation statements)

References 35 publications

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“…In our data sets, tree-based ensemble type models perform better than other models to predict Young's modulus. Ensemble type algorithm showed better performance in other studies to predict materials properties 34,48,49 . Ensemble methods are meta algorithms that combine several base models to produce a better predictive model.…”

Section: Resultsmentioning

confidence: 93%

Machine learning assisted prediction of the Young’s modulus of compositionally complex alloys

Khakurel

Taufique

Roy

et al. 2021

Sci Rep

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We identify compositionally complex alloys (CCAs) that offer exceptional mechanical properties for elevated temperature applications by employing machine learning (ML) in conjunction with rapid synthesis and testing of alloys for validation to accelerate alloy design. The advantages of this approach are scalability, rapidity, and reasonably accurate predictions. ML tools were implemented to predict Young’s modulus of refractory-based CCAs by employing different ML models. Our results, in conjunction with experimental validation, suggest that average valence electron concentration, the difference in atomic radius, a geometrical parameter λ and melting temperature of the alloys are the key features that determine the Young’s modulus of CCAs and refractory-based CCAs. The Gradient Boosting model provided the best predictive capabilities (mean absolute error of 6.15 GPa) among the models studied. Our approach integrates high-quality validation data from experiments, literature data for training machine-learning models, and feature selection based on physical insights. It opens a new avenue to optimize the desired materials property for different engineering applications.

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Section: Resultsmentioning

confidence: 93%

Machine learning assisted prediction of the Young’s modulus of compositionally complex alloys

Khakurel

Taufique

Roy

et al. 2021

Sci Rep

Self Cite

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“…Friedman [43] proposed the gradient boosting machine as a simple and highly flexible machine learning tool. It is a widely used machine learning algorithm that has been shown to be effective in a variety of applications [44][45][46]. The basic idea behind GBM is to build a prediction model using a set of poor learning algorithms, most commonly decision trees.…”

Section: Machine Learning Modelsmentioning

confidence: 99%

DEM- and GIS-Based Analysis of Soil Erosion Depth Using Machine Learning

Nguyen

Chen

2021

IJGI

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Soil erosion is a form of land degradation. It is the process of moving surface soil with the action of external forces such as wind or water. Tillage also causes soil erosion. As outlined by the United Nations Sustainable Development Goal (UN SDG) #15, it is a global challenge to “combat desertification, and halt and reverse land degradation and halt biodiversity loss.” In order to advance this goal, we studied and modeled the soil erosion depth of a typical watershed in Taiwan using 26 morphometric factors derived from a digital elevation model (DEM) and 10 environmental factors. Feature selection was performed using the Boruta algorithm to determine 15 factors with confirmed importance and one tentative factor. Then, machine learning models, including the random forest (RF) and gradient boosting machine (GBM), were used to create prediction models validated by erosion pin measurements. The results show that GBM, coupled with 15 important factors (confirmed), achieved the best result in the context of root mean square error (RMSE) and Nash–Sutcliffe efficiency (NSE). Finally, we present the maps of soil erosion depth using the two machine learning models. The maps are useful for conservation planning and mitigating future soil erosion.

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“…The data used in this study were collected over 30 years of concerted efforts from government and non-government initiatives 16 . The overarching goal of probabilistic machine learning is to make reliable predictions for unknown alloys as well as to accelerate the data collection process to improve the model performance.…”

Section: Resultsmentioning

confidence: 99%

“…Neural Network has been successfully employed in the past by Cole et al 12 and Brun et al 13 to model the creep rupture strength from physical and processing parameters. In a recent article, it was shown that a Gradient Boosting Algorithm 14 can be used to efficiently predict the rupture life 15 and rupture strength 16 of 9–12 wt% Cr ferritic-martensitic steels and austenitic stainless-steels. However, oftentimes the prediction is unreliable for low confidence modeling, where the data is either scarce and highly non-linear or the uncertainty associated with the prediction is not available.…”

Section: Introductionmentioning

confidence: 99%

Uncertainty quantification for Bayesian active learning in rupture life prediction of ferritic steels

Mamun

Taufique

Wenzlick

et al. 2022

Sci Rep

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Three probabilistic methodologies are developed for predicting the long-term creep rupture life of 9–12 wt%Cr ferritic-martensitic steels using their chemical and processing parameters. The framework developed in this research strives to simultaneously make efficient inference along with associated risk, i.e., the uncertainty of estimation. The study highlights the limitations of applying probabilistic machine learning to model creep life and provides suggestions as to how this might be alleviated to make an efficient and accurate model with the evaluation of epistemic uncertainty of each prediction. Based on extensive experimentation, Gaussian Process Regression yielded more accurate inference ($$Pearson\;correlation\;coefficent> 0.95$$ P e a r s o n c o r r e l a t i o n c o e f f i c e n t > 0.95 for the holdout test set) in addition to meaningful uncertainty estimate (i.e., coverage ranges from 94 to 98% for the test set) as compared to quantile regression and natural gradient boosting algorithm. Furthermore, the possibility of an active learning framework to iteratively explore the material space intelligently was demonstrated by simulating the experimental data collection process. This framework can be subsequently deployed to improve model performance or to explore new alloy domains with minimal experimental effort.

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

Cited by 23 publications

References 35 publications

Machine learning assisted prediction of the Young’s modulus of compositionally complex alloys

Machine learning assisted prediction of the Young’s modulus of compositionally complex alloys

DEM- and GIS-Based Analysis of Soil Erosion Depth Using Machine Learning

Uncertainty quantification for Bayesian active learning in rupture life prediction of ferritic steels

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