Predicting materials properties without crystal structure: deep representation learning from stoichiometry

Goodall, Rhys E. A.; Lee, Alpha A.

doi:10.1038/s41467-020-19964-7

Cited by 244 publications

(258 citation statements)

References 47 publications

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“…This allows for consistent comparison to past works [5][6][7]9 . Figure 1 shows the performance metrics from training and testing the models on all the benchmark materials properties outlined above.…”

Section: Benchmark Comparisonsmentioning

confidence: 95%

“…The random forest (RF) model utilizes a Magpiefeaturized CBFV to represent chemistry. This is included as a performance baseline to match similar works 5,9,36 .…”

Section: Benchmark Comparisonsmentioning

confidence: 99%

“…Model weights are updated using the look-ahead 62 and Lamb optimizer 63 with a learning rate that is cycled between 1 × 10 −4 and 6 × 10 −3 every 4 epochs to achieve consistent model convergence. A robust MAE is used as the loss criterion for model performance 9 . The default parameters generalize well when predicting most of the benchmark materials properties.…”

Section: Training Crabnetmentioning

confidence: 99%

“…Predictions for all materials properties were generated using code from the Roost repository 9 . Minor adaptations were made to the code to allow for automated training and benchmarking.…”

Section: Reference Modelsmentioning

confidence: 99%

“…Materials informatics (MI) is the resulting field of research that utilizes statistical and machine learning (ML) approaches in combination with high-throughput computation to analyze the wealth of existing materials information and gain unique insights [2][3][4] . As this wealth has increased, practitioners of MI have increasingly turned to deep learning techniques to model and represent inorganic chemistry, resulting in approaches such as ElemNet, IRNet, CGCNN, SchNet, and Roost [5][6][7][8][9] . In specific cases including CGCNN and SchNet, the compounds are represented using their chemical and structural information 7,8,[10][11][12][13][14][15] .…”

Section: Introductionmentioning

confidence: 99%

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Compositionally restricted attention-based network for materials property predictions

et al. 2021

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In this paper, we demonstrate an application of the Transformer self-attention mechanism in the context of materials science. Our network, the Compositionally Restricted Attention-Based network (), explores the area of structure-agnostic materials property predictions when only a chemical formula is provided. Our results show that ’s performance matches or exceeds current best-practice methods on nearly all of 28 total benchmark datasets. We also demonstrate how ’s architecture lends itself towards model interpretability by showing different visualization approaches that are made possible by its design. We feel confident that and its attention-based framework will be of keen interest to future materials informatics researchers.

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Section: Benchmark Comparisonsmentioning

confidence: 95%

“…The random forest (RF) model utilizes a Magpiefeaturized CBFV to represent chemistry. This is included as a performance baseline to match similar works 5,9,36 .…”

Section: Benchmark Comparisonsmentioning

confidence: 99%

Section: Training Crabnetmentioning

confidence: 99%

“…Predictions for all materials properties were generated using code from the Roost repository 9 . Minor adaptations were made to the code to allow for automated training and benchmarking.…”

Section: Reference Modelsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Compositionally restricted attention-based network for materials property predictions

et al. 2021

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A Property‐Driven Stepwise Design Strategy for Multiple Low‐Melting Alloys via Machine Learning

et al. 2021

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Low-melting alloys (LMAs), composed of metal elements such as Sn, Pb, Bi, Cd, In, Ga, and Zn, have been widely used as fuse, transmission medium, and brazing filler metal in the electronics industry. [1][2][3] However, with the development of environmental protection and electronic technology, binary lead-containing LMAs are insufficient to meet the requirements of the electronics industry. [4,5] From a manufacturing point of view, the melting point may be the first and most important factor to consider. Nevertheless, the research on the melting point of LMAs mostly focuses on binary alloys. Chelikowsky and Anderson [6] found that the melting point of intermetallic binary alloys can be roughly estimated by averaging the melting points of the constituent elements. Pan et al. [7] derived the liquid line equations to calculate the melting point of binary LMAs, and then the equations were extended into multiple alloys. However, the errors of melting point presented an increasing extent with the increasing number of components, and the error of the quaternary alloy samples exceeded 20 C. That may be caused by the complex microstructure and sophisticated phase composition of LMAs. On the contrary, the lack of basic physical and chemical data brings great difficulties to the calculation of melting point for multiple LMAs. Therefore, it is not convenient for us to design multiple LMAs with a specific melting point by using "trial and error" method in tremendous chemical space.In recent years, fast-developing machine learning (ML) methods have been successfully utilized in alloy compositions design. [8][9][10][11][12][13][14] Wang et al. [15] proposed a property-oriented design strategy with the target of ultimate tensile strength and electrical conductivity based on the BP neural network to accelerate the discovery of high-performance copper alloys. Wen et al. [16] formulated a materials design strategy with experimental design algorithms, active learning, and a utility function to search for high entropy alloys with large hardness. Rickman et al. [17] proposed a supervised learning strategy that combines a multiple regression analysis or its generalization, a canonical-correlation analysis (CCA), and a genetic algorithm to efficiently screen the high-entropy alloys. And machine learning has yielded satisfactory performance in the prediction of melting points of different materials. For example, Bhat et al. [18] reported the melting point of organic molecules with a simple ensemble of extreme learning

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Data‐Driven Materials Innovation and Applications

et al. 2022

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Predicting materials properties without crystal structure: deep representation learning from stoichiometry

Cited by 244 publications

References 47 publications

Compositionally restricted attention-based network for materials property predictions

Compositionally restricted attention-based network for materials property predictions

A Property‐Driven Stepwise Design Strategy for Multiple Low‐Melting Alloys via Machine Learning

Data‐Driven Materials Innovation and Applications

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