Abstract
Finding the chemical composition and processing history from a microstructure morphology for heterogeneous materials is desired in many applications. While the simulation methods based on physical concepts such as the phase-field method can predict the spatio-temporal evolution of the materials’ microstructure, they are not efficient techniques for predicting processing and chemistry if a specific morphology is desired. In this study, we propose a framework based on a deep learning approach that enables us to predict the chemistry and processing history just by reading the morphological distribution of one element. As a case study, we used a dataset from spinodal decomposition simulation of Fe–Cr–Co alloy created by the phase-field method. The mixed dataset, which includes both images, i.e., the morphology of Fe distribution, and continuous data, i.e., the Fe minimum and maximum concentration in the microstructures, are used as input data, and the spinodal temperature and initial chemical composition are utilized as the output data to train the proposed deep neural network. The proposed convolutional layers were compared with pretrained EfficientNet convolutional layers as transfer learning in microstructure feature extraction. The results show that the trained shallow network is effective for chemistry prediction. However, accurate prediction of processing temperature requires more complex feature extraction from the morphology of the microstructure. We benchmarked the model predictive accuracy for real alloy systems with a Fe–Cr–Co transmission electron microscopy micrograph. The predicted chemistry and heat treatment temperature were in good agreement with the ground truth.
Highlights
Finding the chemical composition and processing history from a microstructure morphology for heterogeneous materials is desired in many applications
The Convolutional Neural Networks (CNN) and the materials knowledge systems (MKS), proposed in the Kalidindi group based on the idea of using the n-point correlation method for microstructures q uantification[43–45], were used for microstructure quantification and the produced data were employed to predict the strain in the microstructural volume elements
2053 different samples were simulated by the PF method, and the microstructures were constructed for different chemical compositions and temperatures
Summary
Finding the chemical composition and processing history from a microstructure morphology for heterogeneous materials is desired in many applications. Many studies have focused on solving cause-effect design, i.e., finding the material properties from the microstructure or processing history. A less addressed but essential problem is a goal-driven design that tries to find the processing history of the materials from their microstructures In these cases, the optimal microstructure that provides the optimal properties is known, e.g., via physics-based models, and it is desirable to find the chemistry and processing routes that would lead to the desirable microstructure. The CNN and the materials knowledge systems (MKS), proposed in the Kalidindi group based on the idea of using the n-point correlation method for microstructures q uantification[43–45], were used for microstructure quantification and the produced data were employed to predict the strain in the microstructural volume elements. The introduced descriptors outperformed the other descriptors in the prediction of Hartree energies for solid-state materials
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