Applying machine learning to balance performance and stability of high energy density materials
The long-standing performance-stability contradiction issue of high energy density materials (HEDMs) is of extremely complex and multi-parameter nature. Herein, machine learning was employed to handle 28 feature descriptors and 5 properties of detonation and stability of 153 HEDMs, wherein all 21,64...
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sg-ntu-dr.10356-1606772022-08-01T01:23:53Z Applying machine learning to balance performance and stability of high energy density materials Huang, Xiaona Li, Chongyang Tan, Kaiyuan Wen, Yushi Guo, Feng Li, Ming Huang, Yongli Sun, Chang Q. Gozin, Michael Zhang, Lei School of Electrical and Electronic Engineering Centre for Micro-/Nano-electronics (NOVITAS) Engineering::Electrical and electronic engineering Computational Materials Science Energy Materials The long-standing performance-stability contradiction issue of high energy density materials (HEDMs) is of extremely complex and multi-parameter nature. Herein, machine learning was employed to handle 28 feature descriptors and 5 properties of detonation and stability of 153 HEDMs, wherein all 21,648 data used were obtained through high-throughput crystal-level quantum mechanics calculations on supercomputers. Among five models, namely, extreme gradient boosting regression tree (XGBoost), adaptive boosting, random forest, multi-layer perceptron, and kernel ridge regression, were respectively trained and evaluated by stratified sampling and 5-fold cross-validation method. Among them, XGBoost model produced the best scoring metrics in predicting the detonation velocity, detonation pressure, heat of explosion, decomposition temperature, and lattice energy of HEDMs, and XGBoost predictions agreed best with the 1,383 experimental data collected from massive literatures. Feature importance analysis was conducted to obtain data-driven insight into the causality of the performance-stability contradiction and delivered the optimal range of key features for more efficient rational design of advanced HEDMs. Published version The authors greatly acknowledge the financial support from the National Natural Science Foundation of China (Grant Nos. 12072045, 11702266, 11972329, and 51703211). 2022-08-01T01:23:52Z 2022-08-01T01:23:52Z 2021 Journal Article Huang, X., Li, C., Tan, K., Wen, Y., Guo, F., Li, M., Huang, Y., Sun, C. Q., Gozin, M. & Zhang, L. (2021). Applying machine learning to balance performance and stability of high energy density materials. IScience, 24(3), 102240-. https://dx.doi.org/10.1016/j.isci.2021.102240 2589-0042 https://hdl.handle.net/10356/160677 10.1016/j.isci.2021.102240 33748721 2-s2.0-85102249646 3 24 102240 en iScience © 2021 The Authors. This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/). application/pdf |
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Engineering::Electrical and electronic engineering Computational Materials Science Energy Materials Huang, Xiaona Li, Chongyang Tan, Kaiyuan Wen, Yushi Guo, Feng Li, Ming Huang, Yongli Sun, Chang Q. Gozin, Michael Zhang, Lei Applying machine learning to balance performance and stability of high energy density materials |
| description |
The long-standing performance-stability contradiction issue of high energy density materials (HEDMs) is of extremely complex and multi-parameter nature. Herein, machine learning was employed to handle 28 feature descriptors and 5 properties of detonation and stability of 153 HEDMs, wherein all 21,648 data used were obtained through high-throughput crystal-level quantum mechanics calculations on supercomputers. Among five models, namely, extreme gradient boosting regression tree (XGBoost), adaptive boosting, random forest, multi-layer perceptron, and kernel ridge regression, were respectively trained and evaluated by stratified sampling and 5-fold cross-validation method. Among them, XGBoost model produced the best scoring metrics in predicting the detonation velocity, detonation pressure, heat of explosion, decomposition temperature, and lattice energy of HEDMs, and XGBoost predictions agreed best with the 1,383 experimental data collected from massive literatures. Feature importance analysis was conducted to obtain data-driven insight into the causality of the performance-stability contradiction and delivered the optimal range of key features for more efficient rational design of advanced HEDMs. |
| author2 |
School of Electrical and Electronic Engineering |
| author_facet |
School of Electrical and Electronic Engineering Huang, Xiaona Li, Chongyang Tan, Kaiyuan Wen, Yushi Guo, Feng Li, Ming Huang, Yongli Sun, Chang Q. Gozin, Michael Zhang, Lei |
| format |
Article |
| author |
Huang, Xiaona Li, Chongyang Tan, Kaiyuan Wen, Yushi Guo, Feng Li, Ming Huang, Yongli Sun, Chang Q. Gozin, Michael Zhang, Lei |
| author_sort |
Huang, Xiaona |
| title |
Applying machine learning to balance performance and stability of high energy density materials |
| title_short |
Applying machine learning to balance performance and stability of high energy density materials |
| title_full |
Applying machine learning to balance performance and stability of high energy density materials |
| title_fullStr |
Applying machine learning to balance performance and stability of high energy density materials |
| title_full_unstemmed |
Applying machine learning to balance performance and stability of high energy density materials |
| title_sort |
applying machine learning to balance performance and stability of high energy density materials |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/160677 |
| _version_ |
1743119585832337408 |