Quantitative Structure─Permittivity Relationship Study of a Series of Polymers

IF 5.7 Q2 CHEMISTRY, PHYSICAL

ACS Materials Au Pub Date : 2024-01-09 DOI:10.1021/acsmaterialsau.3c00079

Yevhenii Zhuravskyi, Kweeni Iduoku, Meade E. Erickson, Anas Karuth, Durbek Usmanov, Gerardo Casanola-Martin, Maqsud N. Sayfiyev, Dilshod A. Ziyaev, Zulayho Smanova, Alicja Mikolajczyk* and Bakhtiyor Rasulev*,

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Abstract

Dielectric constant is an important property which is widely utilized in many scientific fields and characterizes the degree of polarization of substances under the external electric field. In this work, a structure–property relationship of the dielectric constants (ε) for a diverse set of polymers was investigated. A transparent mechanistic model was developed with the application of a machine learning approach that combines genetic algorithm and multiple linear regression analysis, to obtain a mechanistically explainable and transparent model. Based on the evaluation conducted using various validation criteria, four- and eight-variable models were proposed. The best model showed a high predictive performance for training and test sets, with R² values of 0.905 and 0.812, respectively. Obtained statistical performance results and selected descriptors in the best models were analyzed and discussed. With the validation procedures applied, the models were proven to have a good predictive ability and robustness for further applications in polymer permittivity prediction.

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一系列聚合物的定量结构-脆性关系研究

介电常数是广泛应用于许多科学领域的重要特性，它表征了物质在外电场作用下的极化程度。在这项工作中，研究了不同聚合物的介电常数（ε）的结构-性质关系。应用遗传算法和多元线性回归分析相结合的机器学习方法，建立了一个透明的机理模型，从而获得了一个机理上可解释且透明的模型。根据使用各种验证标准进行的评估，提出了四变量和八变量模型。最佳模型对训练集和测试集显示出较高的预测性能，R2 值分别为 0.905 和 0.812。对所获得的统计性能结果和最佳模型中的选定描述符进行了分析和讨论。应用验证程序证明，这些模型具有良好的预测能力和稳健性，可进一步应用于聚合物介电常数预测。

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来源期刊

ACS Materials Au 材料科学-

CiteScore

5.00

自引率

0.00%

发文量

期刊介绍： ACS Materials Au is an open access journal publishing letters articles reviews and perspectives describing high-quality research at the forefront of fundamental and applied research and at the interface between materials and other disciplines such as chemistry engineering and biology. Papers that showcase multidisciplinary and innovative materials research addressing global challenges are especially welcome. Areas of interest include but are not limited to:Design synthesis characterization and evaluation of forefront and emerging materialsUnderstanding structure property performance relationships and their underlying mechanismsDevelopment of materials for energy environmental biomedical electronic and catalytic applications