Machine Learning Prediction of the Critical Cooling Rate for Metallic Glasses from Expanded Datasets and Elemental Features

Afflerbach, Benjamin; Francis, Carter; Schultz, L.; Spethson, Janine T.; Meschke, Vanessa; Strand, Elliot; Ward, Logan; Perepezko, John H.; Thoma, Dan J.; Voyles, Paul M.; Szlufarska, Izabela; Morgan, Dane

doi:10.1021/acs.chemmater.1c03542

Cited by 15 publications

(3 citation statements)

References 42 publications

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“…Out of the 309 unique datapoints, there were 222 unique material compositions (some compositions had multiple values originating from different research papers) in the standardized database, and after removing non-metallic systems standardized-MG database contained 298 unique datapoints for 217 unique material compositions. This size of 217 unique compositions is significantly larger than the previous largest hand-curated database published by Afflerbach et al 40 , which had just 77 entries. This result shows that, at least in this case, ChatExtract can generate more quality data with much less time than human extraction efforts.…”

Section: Resultsmentioning

confidence: 87%

Extracting accurate materials data from research papers with conversational language models and prompt engineering

Polak,

Morgan

2024

Nat Commun

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There has been a growing effort to replace manual extraction of data from research papers with automated data extraction based on natural language processing, language models, and recently, large language models (LLMs). Although these methods enable efficient extraction of data from large sets of research papers, they require a significant amount of up-front effort, expertise, and coding. In this work, we propose the method that can fully automate very accurate data extraction with minimal initial effort and background, using an advanced conversational LLM. consists of a set of engineered prompts applied to a conversational LLM that both identify sentences with data, extract that data, and assure the data’s correctness through a series of follow-up questions. These follow-up questions largely overcome known issues with LLMs providing factually inaccurate responses. can be applied with any conversational LLMs and yields very high quality data extraction. In tests on materials data, we find precision and recall both close to 90% from the best conversational LLMs, like GPT-4. We demonstrate that the exceptional performance is enabled by the information retention in a conversational model combined with purposeful redundancy and introducing uncertainty through follow-up prompts. These results suggest that approaches similar to , due to their simplicity, transferability, and accuracy are likely to become powerful tools for data extraction in the near future. Finally, databases for critical cooling rates of metallic glasses and yield strengths of high entropy alloys are developed using .

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Section: Resultsmentioning

confidence: 87%

Extracting accurate materials data from research papers with conversational language models and prompt engineering

Polak,

Morgan

2024

Nat Commun

Self Cite

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“…Within these, 129 are unique systems (multiple values are reported for some systems and we kept these to allow the user to manage them as they wish). The database is larger than the size of a recently published manually curated database of critical cooling rates, 59 which is the most state-of-the-art and complete such database of which we are aware, and consists of only 77 unique compound datapoints. To provide comparison to other existing methods, we used ChemDataExtractor2 (CDE2), 15 a state-of-the-art named entity recognition (NER) based data extraction tool.…”

Section: Discussionmentioning

confidence: 99%

Flexible, model-agnostic method for materials data extraction from text using general purpose language models

Polak,

Modi,

Latosinska

et al. 2024

Digital Discovery

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“…39 In particular, a variety of ML algorithms have been applied to correlate the glass structure and chemistry with elasticity, 29 the propensity for plastic deformation, 16,17,23,33 and thermal and physical properties. [18][19][20][21][22][24][25][26][27][28][29][30][31][32] In regard to GFA, ML models demonstrate success in predicting the glass transition temperature, 35,36 the critical cooling rate, 37 and the critical casting diameter of MGs, 15,21,26,28 and further identify new glass-forming systems, 22,31 using random forest, 25,32 support vector machine (SVM), 28 and neural network 18,31,34 algorithms. Until now, the ML studies of GFA have been mainly focused on binary and ternary alloy systems, and further efforts are required to explore multicomponent alloys using ML algorithms.…”

Section: Introductionmentioning

confidence: 99%

Machine Learning-Guided Exploration of Glass-Forming Ability in Multicomponent Alloys

Yao

Sullivan

Yan

et al. 2022

JOM

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The prediction of glass-forming ability (GFA) in alloy systems is a challenging problem in material science as well as for metallurgical applications. In this study, we build artificial neural network (ANN) models to investigate the GFA of multicomponent alloys, based on the datasets assembled from ternary alloys as well as quinary alloys prepared by magnetron sputtering. Through training the ANN models with different combinations of datasets, we tackle the problem of the influence of the data source on the model performance, especially the generalizability of the models in predicting the GFA in unseen multicomponent alloy systems. The ANN model trained on a combined dataset exhibits the best performance, specifically low root mean square error in leaveone-alloy-system-out validation and high model robustness, for several CoCrFeNi-based multicomponent alloys. To further verify the ANN models, we synthesize CoCrFeNi-Mo metallic thin films by magnetron co-sputtering and characterize the structure and phase information via x-ray diffraction and electron microscopy. The outcomes of our experiments agree reasonably well with the ANN model predictions, indicating that the data-driven machine learning approach can be a useful tool in the future design of multicomponent amorphous alloys.

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Machine Learning Prediction of the Critical Cooling Rate for Metallic Glasses from Expanded Datasets and Elemental Features

Cited by 15 publications

References 42 publications

Extracting accurate materials data from research papers with conversational language models and prompt engineering

Extracting accurate materials data from research papers with conversational language models and prompt engineering

Flexible, model-agnostic method for materials data extraction from text using general purpose language models

Machine Learning-Guided Exploration of Glass-Forming Ability in Multicomponent Alloys

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