Machine learning based feature engineering for thermoelectric materials by design
Availability of material datasets through high performance computing has enabled the use of machine learning to not only discover correlations and employ materials informatics to perform screening, but also to take the first steps towards materials by design. Computational materials databases are we...
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sg-ntu-dr.10356-1748842024-04-19T15:59:54Z Machine learning based feature engineering for thermoelectric materials by design Vaitesswar, U. S. Bash, Daniil Huang, Tan Recatala-Gomez, Jose Deng, Tianqi Yang, Shuo-Wang Wang, Xiaonan Hippalgaonkar, Kedar School of Materials Science and Engineering Institute of Materials Research and Engineering, A*STAR Engineering Machine learning Thermoelectric materials Availability of material datasets through high performance computing has enabled the use of machine learning to not only discover correlations and employ materials informatics to perform screening, but also to take the first steps towards materials by design. Computational materials databases are well-labelled and provide a fertile ground for predicting both ground-state and functional properties of materials. However, a clear design approach that allows prediction of materials with the desired functional performance does not yet exist. In this work, we train various machine learning models on a dataset curated from a combination of Materials Project as well as computationally calculated thermoelectric electronic power factor using a constant relaxation time Boltzmann transport equation (BoltzTrap). We show that simple random forest-based machine learning models outperform more complex neural network-based approaches on the moderately sized dataset and also allow for interpretability. In addition, when trained on only cubic material systems, the best performing machine learning model employs a perturbative scanning approach to find new candidates in Materials Project that it has never seen before, and automatically converges upon half-Heusler alloys as promising thermoelectric materials. We validate this prediction by performing density functional theory and BoltzTrap calculations to reveal accurate matching. One of those predicted to be a good material, NbFeSb, has been studied recently by the thermoelectric community; from this study, we propose four new half-Heusler compounds as promising thermoelectric materials - TiGePt, ZrInAu, ZrSiPd and ZrSiPt. Our approach is generalizable to extrapolate into previously unexplored material spaces and establishes an automated pipeline for the development of high-throughput functional materials. Agency for Science, Technology and Research (A*STAR) National Research Foundation (NRF) Published version The authors acknowledge funding from the Accelerated Materials Development for Manufacturing Program at A*STAR via the AME Programmatic Fund by the Agency for Science, Technology and Research under grant no. A1898b0043. KH also acknowledges support from the NRF Fellowship NRF-NRFF13-2021-0011. 2024-04-15T05:49:19Z 2024-04-15T05:49:19Z 2024 Journal Article Vaitesswar, U. S., Bash, D., Huang, T., Recatala-Gomez, J., Deng, T., Yang, S., Wang, X. & Hippalgaonkar, K. (2024). Machine learning based feature engineering for thermoelectric materials by design. Digital Discovery, 3(1), 210-220. https://dx.doi.org/10.1039/d3dd00131h 2635-098X https://hdl.handle.net/10356/174884 10.1039/d3dd00131h 2-s2.0-85181259361 1 3 210 220 en A1898b0043 NRF-NRFF13-2021-0011 Digital Discovery © 2024 The Author(s). Published by the Royal Society of Chemistry. This article is licensed under a Creative Commons Attribution-NonCommercial 3.0 Unported Licence. application/pdf |
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Engineering Machine learning Thermoelectric materials Vaitesswar, U. S. Bash, Daniil Huang, Tan Recatala-Gomez, Jose Deng, Tianqi Yang, Shuo-Wang Wang, Xiaonan Hippalgaonkar, Kedar Machine learning based feature engineering for thermoelectric materials by design |
| description |
Availability of material datasets through high performance computing has enabled the use of machine learning to not only discover correlations and employ materials informatics to perform screening, but also to take the first steps towards materials by design. Computational materials databases are well-labelled and provide a fertile ground for predicting both ground-state and functional properties of materials. However, a clear design approach that allows prediction of materials with the desired functional performance does not yet exist. In this work, we train various machine learning models on a dataset curated from a combination of Materials Project as well as computationally calculated thermoelectric electronic power factor using a constant relaxation time Boltzmann transport equation (BoltzTrap). We show that simple random forest-based machine learning models outperform more complex neural network-based approaches on the moderately sized dataset and also allow for interpretability. In addition, when trained on only cubic material systems, the best performing machine learning model employs a perturbative scanning approach to find new candidates in Materials Project that it has never seen before, and automatically converges upon half-Heusler alloys as promising thermoelectric materials. We validate this prediction by performing density functional theory and BoltzTrap calculations to reveal accurate matching. One of those predicted to be a good material, NbFeSb, has been studied recently by the thermoelectric community; from this study, we propose four new half-Heusler compounds as promising thermoelectric materials - TiGePt, ZrInAu, ZrSiPd and ZrSiPt. Our approach is generalizable to extrapolate into previously unexplored material spaces and establishes an automated pipeline for the development of high-throughput functional materials. |
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School of Materials Science and Engineering |
| author_facet |
School of Materials Science and Engineering Vaitesswar, U. S. Bash, Daniil Huang, Tan Recatala-Gomez, Jose Deng, Tianqi Yang, Shuo-Wang Wang, Xiaonan Hippalgaonkar, Kedar |
| format |
Article |
| author |
Vaitesswar, U. S. Bash, Daniil Huang, Tan Recatala-Gomez, Jose Deng, Tianqi Yang, Shuo-Wang Wang, Xiaonan Hippalgaonkar, Kedar |
| author_sort |
Vaitesswar, U. S. |
| title |
Machine learning based feature engineering for thermoelectric materials by design |
| title_short |
Machine learning based feature engineering for thermoelectric materials by design |
| title_full |
Machine learning based feature engineering for thermoelectric materials by design |
| title_fullStr |
Machine learning based feature engineering for thermoelectric materials by design |
| title_full_unstemmed |
Machine learning based feature engineering for thermoelectric materials by design |
| title_sort |
machine learning based feature engineering for thermoelectric materials by design |
| publishDate |
2024 |
| url |
https://hdl.handle.net/10356/174884 |
| _version_ |
1800916221695098880 |