Structure prediction of multi-principal element alloys using ensemble learning

Choudhury, Amitava; Konnur, Tanmay; Chattopadhyay, Paramita; Pal, Snehanshu

doi:10.1108/ec-04-2019-0151

Cited by 32 publications

(14 citation statements)

References 72 publications

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“…Most of the earlier works on machine learning based phase predictions of HEA/MPEA [19,35,36] do not consider the composition vector of alloy as a fingerprint in the model. Neither do these models associate the composition vector with other fingerprints.…”

Section: Data-driven Model With Gui Interface For Phase Predictionmentioning

confidence: 99%

pyMPEALab Toolkit for Accelerating Phase Design in Multi-principal Element Alloys

et al. 2021

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Multi-principal element alloys (MPEAs) occur at or nearby the centre of the multicomponent phase space, and they have the unique potential to be tailored with a blend of several desirable properties for the development of materials of future. The lack of universal phase diagrams for MPEAs has been a major challenge in the accelerated design of products with these materials. This study aims to solve this issue by employing data-driven approaches in phase prediction. A MPEA is first represented by numerical fingerprints (composition, atomic size difference , electronegativity , enthalpy of mixing , entropy of mixing , dimensionless $$\Omega$$ Ω parameter, valence electron concentration and phase types ), and an artificial neural network (ANN) is developed upon the datasets of these numerical descriptors. A pyMPEALab GUI interface is developed on the top of this ANN model with a computational capability to associate composition features with remaining other input features. With the GUI interface, an user can predict the phase(s) of a MPEA by entering solely the information of composition. It is further explored on how the knowledge of phase(s) prediction in composition-varied $$\hbox {Al}_x$$ Al x CrCoFeMnNi and $$\hbox {CoCrNiNb}_x$$ CoCrNiNb x can help in understanding the mechanical behavior of these MPEAs. Graphic Abstract

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Section: Data-driven Model With Gui Interface For Phase Predictionmentioning

confidence: 99%

pyMPEALab Toolkit for Accelerating Phase Design in Multi-principal Element Alloys

et al. 2021

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“…The DT predicated ensemble algorithm can give better performance for independent base learners, which can be achieved through randomization. While growing the trees, a better tree diversity is needed for randomization, which facilitates truncating the correlation [38]. A robust and stable classifier (model) in supervised ML tasks with accurate predictions can be achieved utilizing an ensemble method to reduce the factors, i.e.…”

Section: Model (Extra Tree Classifier)mentioning

confidence: 99%

“…variance, noise, and bias. Nevertheless, the main drawback that an ensemble learner faces is the imminent rise in computational time due to multiple individual classifiers training [38]. As a result, the ET algorithm has been highlighted, which works virtually akin to, yet more expeditious than the random forest algorithm.…”

Section: Model (Extra Tree Classifier)mentioning

confidence: 99%

Designing hexagonal close packed high entropy alloys using machine learning

Bejjipurapu¹,

Bajpai²,

Gurao³

et al. 2021

Modelling Simul. Mater. Sci. Eng.

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High entropy alloys (HEAs) have drawn significant interest in the materials research community owing to their remarkable physical and mechanical properties. These improved physicochemical properties manifest due to the formation of simple solid solution phases with unique microstructures. Though several pathbreaking HEAs have been reported, the field of alloy design, which has the potential to guide alloy screening, is still an open topic hindering the development of new HEA compositions, particularly ones with hexagonal close packed (hcp) crystal structure. In this work, an attempt has been made to develop an intelligent extra tree (ET) classification model based on the key thermodynamic and structural properties, to predict the phase evolution in HEAs. The results of correlation analysis suggest that all the selected thermodynamic and structural features are viable candidates for the descriptor dataset. Testing accuracy of above 90% along with excellent performance matrices for the ET classifier reveal the robustness of the model. The model can be employed to design novel hcp HEAs and as a valuable tool in the alloy design of HEAs in the future.

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“…In machine learning, logistic regression is useful while obtaining a particular class or event existing from the actual class table . Various classification techniques such as logistic regression, support vector machine, K-nearest neighbor, and random forest is used to compare the results [34][35][36][37][38]. In this paper, a multi class classification is discussed to predict the thermomechanical processing routes, namely hot rolled (HR), cold drawn (CR) annealed cold drawn (ACR), and spheroidite annealed cold drawn (SCR) as describe in table 1.…”

Section: Computational Modelmentioning

confidence: 99%

Processing Technique Selection for Steels Based on Mechanical Properties Using Machine Learning Framework

Choudhury

2021

Preprint

Self Cite

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Prediction of process route from materials with a desired set of property is one of the fundamental issues in the perspective of the materials design aspect. The parameter space is often too large to be bound since there are too many possibilities. However, in the areas with limited theoretical access, artificial learning techniques can be attempted by using the available data of the candidate materials. In this study, a computational method has been proposed to predict the different process routes of steel constituted taking composition and desired mechanical properties as inputs. First of all, historical data of the actual rolling process was collected, cleaned, and integrated. Further, the dataset is divided into four different classes based on the rolling process data. Then, to find out the essential characteristics of variables, feature correlation among various features has been calculated. A state-of-art machine learning prediction methods such as logistic regression, K- nearest neighbor, Support vector machine, and the random forest are studied to implement the prediction model. In order to avoid the overfitting of the model, k fold cross-validation is applied to the model, and achieve a realistic prediction result with an accuracy of 97%. The F1-score of the classification model is 0.86, and the kappa score is 0.95, which comply that the model has excellent learning and speculation ability and the precise forecast of steel process routes based on the given input parameters.

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Structure prediction of multi-principal element alloys using ensemble learning

Cited by 32 publications

References 72 publications

pyMPEALab Toolkit for Accelerating Phase Design in Multi-principal Element Alloys

pyMPEALab Toolkit for Accelerating Phase Design in Multi-principal Element Alloys

Designing hexagonal close packed high entropy alloys using machine learning

Processing Technique Selection for Steels Based on Mechanical Properties Using Machine Learning Framework

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