Impact of Oxygen Containing Carbonyl and Ether Groups on Dielectric Properties of Poly(oxa)norbornene Cyclic Olefins

IF 2.1 3区物理与天体物理 Q3 PHYSICS, APPLIED Journal of Advanced Dielectrics Pub Date : 2023-04-15 DOI:10.1142/s2010135x23410059

Chao Wu, Ajinkya A. Deshmukh, Lihua Chen, R. Ramprasad, G. Sotzing, Yang Cao

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Abstract

Flexible dielectric polymers that can withstand high electric field and simultaneously have high dielectric constant are desired for high-density energy storage. Here, we systematically investigated the impact of oxygen-containing ether and carbonyl groups in the backbone structure on dielectric properties of a series of cyclic olefin. In comparison to the influence of the –CF 3 pendant groups that had more impact on the dielectric constant rather than the band gap, the change of the backbone structure affected both the dielectric constant and band gaps. The one polymer with ether and carbonyl groups in the backbone has the largest band gap and highest discharge efficiency, while it has the lowest dielectric constant. The polymer without any ether groups in the backbone has the smallest band gap and lowest discharge efficiency, but it has the highest dielectric constant. Polymers that have no dipolar relaxation exhibit an inversely correlated dielectric constant and band gap. Enhancing the dipolar relaxation through rational molecular structure design can be a novel way to break through the exclusive constraint of dielectric constant and band gap for high-density energy storage.

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含氧羰基和醚基对聚降冰片烯环烯烃介电性能的影响

能够承受高电场并同时具有高介电常数的柔性介电聚合物是高密度储能所需要的。本文系统地研究了一系列环烯烃骨架结构中含氧醚和羰基对其介电性能的影响。相对于- cf3悬垂基团对介电常数的影响大于对带隙的影响，主链结构的变化对介电常数和带隙都有影响。含有醚和羰基的聚合物具有最大的带隙和最高的放电效率，而介电常数则最低。主链中没有任何醚基团的聚合物带隙最小，放电效率最低，但介电常数最高。没有偶极弛豫的聚合物表现出负相关的介电常数和带隙。通过合理的分子结构设计增强偶极弛豫可以突破介电常数和带隙的排他性限制，实现高密度储能。

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来源期刊

Journal of Advanced Dielectrics PHYSICS, APPLIED-

CiteScore

3.80

自引率

6.50%

发文量

审稿时长

18 weeks

期刊介绍： The Journal of Advanced Dielectrics is an international peer-reviewed journal for original contributions on the understanding and applications of dielectrics in modern electronic devices and systems. The journal seeks to provide an interdisciplinary forum for the rapid communication of novel research of high quality in, but not limited to, the following topics: Fundamentals of dielectrics (ab initio or first-principles calculations, density functional theory, phenomenological approaches). Polarization and related phenomena (spontaneous polarization, domain structure, polarization reversal). Dielectric relaxation (universal relaxation law, relaxor ferroelectrics, giant permittivity, flexoelectric effect). Ferroelectric materials and devices (single crystals and ceramics). Thin/thick films and devices (ferroelectric memory devices, capacitors). Piezoelectric materials and applications (lead-based piezo-ceramics and crystals, lead-free piezoelectrics). Pyroelectric materials and devices Multiferroics (single phase multiferroics, composite ferromagnetic ferroelectric materials). Electrooptic and photonic materials. Energy harvesting and storage materials (polymer, composite, super-capacitor). Phase transitions and structural characterizations. Microwave and milimeterwave dielectrics. Nanostructure, size effects and characterizations. Engineering dielectrics for high voltage applications (insulation, electrical breakdown). Modeling (microstructure evolution and microstructure-property relationships, multiscale modeling of dielectrics).