Correlation analysis of materials properties by machine learning: illustrated with stacking fault energy from first-principles calculations in dilute fcc-based alloys

Chong, Xiaoyu; Shang, Shun‐Li; Krajewski, Adam M.; Shimanek, John D.; Du, Weihang; Wang, Yi; Feng, Jing; Shin, Dongwon; Beese, Allison M.; Liu, Zhe

doi:10.1088/1361-648x/ac0195

Cited by 19 publications

(3 citation statements)

References 77 publications

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“…The α-AlFeMnCrSi phase has the highest stress, which may be related to the strong Si-Cr bonds. Variations in the stacking fault energies and ideal tensile strengths can be analyzed in terms of the differential charge-density distributions [35,[52][53][54][55]. A dense charge density usually means strong chemical bonding among the atoms.…”

Section: Stacking Fault Energy and Tensile Propertiesmentioning

confidence: 99%

Exploring the Relationship between the Structural Characteristics and Mechanical Behavior of Multicomponent Fe-Containing Phases: Experimental Studies and First-Principles Calculations

Wang,

Zhang,

Nagaumi

et al. 2023

Molecules

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A comprehensive understanding of the structural characteristics and mechanical behavior of Fe-containing phases is important for high-Fe-level Al-Si alloys. In this paper, the crystal characteristics, thermal stability, thermophysical properties and mechanical behavior of multicomponent α-AlFeMnSi and α-AlFeMnCrSi phases are investigated by experimental studies and first-principles calculations. The results indicate that it is easier for Fe and Cr to substitute the Mn-12j site in α-AlMnSi in thermodynamics; Cr is preferred to Fe for substituting Mn-12j/k sites due to its lower formation enthalpy after single substitutions at Mn atom sites. The α-AlFeMnCrSi phase shows higher thermal stability, modulus and intrinsic hardness and a lower volumetric thermal expansion coefficient at different temperatures due to the strong chemical bonding of Si-Fe and Si-Cr. Moreover, the α-AlFeMnCrSi phase has a higher ideal strength (10.65 GPa) and lower stacking fault energy (1.10 × 103 mJ/m2). The stacking fault energy evolution of the different Fe-containing phases is mainly attributed to the differential charge-density redistribution. The strong chemical bonds of Si-Fe, Si-Mn and Si-Cr are important factors affecting the thermophysical and mechanical behaviors of the α-AlFeMnCrSi phase.

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Section: Stacking Fault Energy and Tensile Propertiesmentioning

confidence: 99%

Exploring the Relationship between the Structural Characteristics and Mechanical Behavior of Multicomponent Fe-Containing Phases: Experimental Studies and First-Principles Calculations

Wang,

Zhang,

Nagaumi

et al. 2023

Molecules

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“…The application of NNs, also widely known as artificial neural networks or simulated neural networks, has shown success in many scientific domains, including the materials sciences. [10][11][12][13][14][15][16][17][18][19] Inspired by the networks of neurons in the human brain, NNs are comprised of layers of neuron nodes, including an input layer, one or more hidden layers, and an output layer. Each node, or artificial neuron, connects to another and has an associated weight and threshold, also known as the activation function.…”

Section: Computational Approachmentioning

confidence: 99%

A Neural Network Approach to Predict Gibbs Free Energy of Ternary Solid Solutions

Laiu

Yang

Pasini

et al. 2022

J. Phase Equilib. Diffus.

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We present a data-centric deep learning (DL) approach using neural networks (NNs) to predict the thermodynamics of ternary solid solutions. We explore how NNs can be trained with a dataset of Gibbs free energies computed from a CALPHAD database to predict ternary systems as a function of composition and temperature. We have chosen the energetics of the FCC solid solution phase in 226 binaries consisting of 23 elements at 11 different temperatures to demonstrate the feasibility. The number of binary data points included in the present study is 102,000. We select six ternaries to augment the binary dataset to investigate their influence on the NN prediction accuracy. We examine the sensitivity of data sampling on the prediction accuracy of NNs over selected ternary systems. It is anticipated that the current DL workflow can be further elevated by integrating advanced descriptors beyond the elemental composition and more curated training datasets to improve prediction accuracy and applicability.

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“…As most reports of HEAs in the literature do not include shear modulus G and fracture toughness K IC , reference values were derived based on a linear combination (LC) of the pure elemental properties from DFT calculations. 48 The shear modulus was approximated as a simple LC of elemental shear modulus values, while fracture toughness was obtained using Rice's model, 49 given by the equation…”

Section: B Building a Generative Modelmentioning

confidence: 99%

Generative deep learning as a tool for inverse design of high-entropy refractory alloys

Debnath¹,

Krajewski²,

Lin³

et al. 2021

Preprint

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Generative deep learning is powering a wave of new innovations in materials design.In this article, we discuss the basic operating principles of these methods and their advantages over rational design through the lens of a case study on refractory highentropy alloys for ultra-high-temperature applications. We present our computational infrastructure and workflow for the inverse design of new alloys powered by these methods. Our preliminary results show that generative models can learn complex relationships in order to generate novelty on demand, making them a valuable tool for materials informatics.

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Correlation analysis of materials properties by machine learning: illustrated with stacking fault energy from first-principles calculations in dilute fcc-based alloys

Cited by 19 publications

References 77 publications

Exploring the Relationship between the Structural Characteristics and Mechanical Behavior of Multicomponent Fe-Containing Phases: Experimental Studies and First-Principles Calculations

Exploring the Relationship between the Structural Characteristics and Mechanical Behavior of Multicomponent Fe-Containing Phases: Experimental Studies and First-Principles Calculations

A Neural Network Approach to Predict Gibbs Free Energy of Ternary Solid Solutions

Generative deep learning as a tool for inverse design of high-entropy refractory alloys

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