Improving the mechanical and high-frequency dielectric properties of the bio-based thermoplastic copolyesters using fatty acid dimer diol and aromatic diester monomers

IF 5.8 2区化学 Q1 POLYMER SCIENCE

European Polymer Journal Pub Date : 2025-06-18 DOI:10.1016/j.eurpolymj.2025.114070

Yu-Chiung Li , Yi-An Tsai , Po-Yi Lu , Mitsuru Ueda , Yan-Cheng Lin , Wen-Chang Chen

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引用次数: 0

Abstract

Thermoplastic copolyesters (TPCs) are crucial structural components in a wide range of high-performance applications where exceptional processing temperatures and remarkable flexibility are essential. Among them, fatty acid dimer diol (DDO), a bio-based compound, has been used as the soft segment in bio-based TPCs through various synthesis methods. However, few studies have compared the mechanical and dielectric properties of TPCs with DDO and aromatic diester monomers of varying structures to evaluate their suitability for soft electronic devices. The objective of this study is to investigate the impact of structural isomerism and rigidity on the properties of TPCs by incorporating three different aromatic diester monomers with distinct structures into the materials. The copolymerization of a series of TPCs via melt polycondensation, catalyzed by titanium butoxide and butyltin hydroxide oxide, was carried out using alkyl diols and aromatic diesters such as DDO, 1,4-butanediol, dimethyl terephthalate, dimethyl isophthalate (DMI), and dimethyl-2,6-naphthalenedicarboxylate (NDC), resulting in promising outcomes. The results show that introducing a higher proportion of DDO not only increases the bio-based content of TPCs but also enhances their flexibility, effectively reducing both the dielectric constant (D_k) and dissipation factor (D_f) at high frequencies. Notably, under the exact condition of adding 20 mol% DDO, copolymerizing with 20 mol% meta-positioned DMI significantly improves the flexibility of TPCs, with the elongation at break increasing to 607 % from 109 % before copolymerization, although the D_k and D_f slightly increase. On the other hand, when 20 mol% DDO is added, copolymerizing with the more rigid NDC increases the mechanical strength. It effectively lowers the dielectric property, as the D_k of the copolymerized 20 mol% NDC decreases from 2.43 to 2.32 at 29 GHz. These results are closely related to the solid-state stacking revealed by their distinct refractive index and crystallinity. This study, through the development of a series of bio-based TPCs, effectively explores the relationship between the mechanical and dielectric properties of these materials, providing valuable insights for the design of flexible electronic components and the development of bio-based materials.

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利用脂肪酸二聚体二醇和芳香二酯单体改善生物基热塑性共聚酯的机械性能和高频介电性能

热塑性共聚酯（tpc）是各种高性能应用中至关重要的结构部件，在这些应用中，特殊的加工温度和卓越的灵活性是必不可少的。其中，脂肪酸二聚二醇（DDO）是一种生物基化合物，通过各种合成方法作为生物基tpc的软段。然而，很少有研究将tpc与不同结构的DDO和芳香二酯单体的力学和介电性能进行比较，以评估其在软电子器件中的适用性。本研究的目的是通过将三种不同结构的芳香二酯单体掺入tpc材料中，研究结构异构和刚性对tpc性能的影响。以烷基二醇和芳香二酯如DDO、1,4-丁二醇、对苯二甲酸二甲酯、异苯二甲酸二甲酯（DMI）和2,6-萘二羧酸二甲酯（NDC）为原料，在丁氧化钛和氧化丁基锡的催化下，通过熔融缩聚反应共聚了一系列tpc，取得了良好的效果。结果表明，加入较高比例的DDO不仅可以提高tpc的生物基含量，还可以增强tpc的柔韧性，有效降低tpc的高频介电常数（Dk）和耗散因子（Df）。值得注意的是，在添加20 mol% DDO的精确条件下，与20 mol%的元位DMI共聚显著提高了tpc的柔韧性，断裂伸长率从共聚前的109%提高到607%，尽管Dk和Df略有增加。另一方面，当加入20 mol%的DDO时，与刚性较强的NDC共聚，机械强度增加。在29 GHz时，20 mol% NDC的Dk从2.43降低到2.32，有效地降低了介电性能。这些结果与它们不同的折射率和结晶度所揭示的固态堆积密切相关。本研究通过开发一系列生物基tpc，有效地探索了这些材料的力学性能和介电性能之间的关系，为柔性电子元件的设计和生物基材料的发展提供了有价值的见解。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

European Polymer Journal 化学-高分子科学

CiteScore

9.90

自引率

10.00%

发文量

691

审稿时长

23 days

期刊介绍： European Polymer Journal is dedicated to publishing work on fundamental and applied polymer chemistry and macromolecular materials. The journal covers all aspects of polymer synthesis, including polymerization mechanisms and chemical functional transformations, with a focus on novel polymers and the relationships between molecular structure and polymer properties. In addition, we welcome submissions on bio-based or renewable polymers, stimuli-responsive systems and polymer bio-hybrids. European Polymer Journal also publishes research on the biomedical application of polymers, including drug delivery and regenerative medicine. The main scope is covered but not limited to the following core research areas: Polymer synthesis and functionalization • Novel synthetic routes for polymerization, functional modification, controlled/living polymerization and precision polymers. Stimuli-responsive polymers • Including shape memory and self-healing polymers. Supramolecular polymers and self-assembly • Molecular recognition and higher order polymer structures. Renewable and sustainable polymers • Bio-based, biodegradable and anti-microbial polymers and polymeric bio-nanocomposites. Polymers at interfaces and surfaces • Chemistry and engineering of surfaces with biological relevance, including patterning, antifouling polymers and polymers for membrane applications. Biomedical applications and nanomedicine • Polymers for regenerative medicine, drug delivery molecular release and gene therapy The scope of European Polymer Journal no longer includes Polymer Physics.