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Prediction and Interpretability Study of the Glass Transition Temperature of Polyimide Based on Machine Learning with Quantitative Structure–Property Relationship (Tg-QSPR)

Authors :
Zhang, Tianyong
Wang, Suisui
Chai, Yamei
Yu, Jianing
Zhu, Wenxuan
Li, Liang
Li, Bin
Source :
The Journal of Physical Chemistry - Part B; September 2024, Vol. 128 Issue: 36 p8807-8817, 11p
Publication Year :
2024

Abstract

The glass transition temperature (Tg) is a crucial characteristic of polyimides (PIs). Developing a Tgpredictive model using machine learning methodologies can facilitate the design of PI structures and expedite the development process. In this investigation, a data set comprising 1257 PIs was assembled, with Tgvalues determined using differential scanning calorimetry. 210 molecular descriptors were computed using RDKit, and subsequently, six distinct feature selection methodologies were employed to refine the descriptor set. Quantitative structure–property relationship models targeting Tg(Tg-QSPR) were then constructed using five ensemble learning algorithms and one deep learning algorithm. These models exhibited high predictive accuracy and robustness, with the CATBoost model demonstrating the highest accuracy, achieving a coefficient of determination of 0.823 for the test set, a mean absolute error of 20.1 °C, and a root-mean-square error of 29.0 °C. The study identified the NumRotatableBonds descriptor as particularly influential on Tg, showing a negative correlation with the property. Additionally, the model’s accuracy was validated using ten new PI films not included in the original data set, resulting in absolute errors ranging from 2.5 to 26.9 °C and absolute percentage error rates of 1.0–12.8%. These findings underscore the importance of utilizing extensive and diverse data sets for predictive modeling to enhance accuracy and stability. Furthermore, exploring the interpretability of the model and experimentally validating newly synthesized PIs have augmented the practical utility of the model. Under the guidance of the Tg-QSPR models, it will be possible to accelerate the performance prediction and structural design of PIs in the future.

Details

Language :
English
ISSN :
15206106 and 15205207
Volume :
128
Issue :
36
Database :
Supplemental Index
Journal :
The Journal of Physical Chemistry - Part B
Publication Type :
Periodical
Accession number :
ejs66869685
Full Text :
https://doi.org/10.1021/acs.jpcb.4c00756