通过协同优化偶极玻璃的带隙和极化来提高聚合物电介质的高温储能性能。

Enhanced high-temperature energy storage performances in polymer dielectrics by synergistically optimizing band-gap and polarization of dipolar glass.

作者信息

Yang Minzheng, Ren Weibin, Jin Zenghui, Xu Erxiang, Shen Yang

机构信息

State Key Lab of New Ceramics and Fine Processing, School of Materials Science and Engineering, Tsinghua University, Beijing, China.

出版信息

Nat Commun. 2024 Oct 5;15(1):8647. doi: 10.1038/s41467-024-52791-8.

DOI:10.1038/s41467-024-52791-8

PMID:39368966

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11455895/

Abstract

Polymer dielectrics play an irreplaceable role in electrostatic capacitors in modern electrical systems, and have been intensively studied with their polarization and breakdown strength (E) optimized for high discharged energy density (U) at elevated temperatures. Small molecules have been explored as fillers, yet they deteriorate thermal stability of matrix which limits their optimal loading to ~1 wt%. Herein, we develop a polymer blend dielectric consisting of common polyimide and a bifunctional dipolar glass polymer which are synthesized from two small molecule components with wide band-gap and large dipole moment. The bifunctional dipolar glass with large molecular weight not only maintains thermal stability of polymer blends even at a high loading of 10 wt%, but also induces substantial enhancement in polarization and E than any of individual components does, achieving an ultrahigh U of 8.34 J cm (150 °C) and 6.21 J cm (200 °C) with a charge-discharge efficiency of 90%.

摘要

聚合物电介质在现代电气系统的静电电容器中发挥着不可替代的作用，并且已经针对高温下的高放电能量密度（U）对其极化和击穿强度（E）进行了深入研究以实现优化。小分子已被用作填料进行探索，但它们会降低基体的热稳定性，这限制了它们的最佳负载量至约1 wt%。在此，我们开发了一种由普通聚酰亚胺和双功能偶极玻璃聚合物组成的聚合物共混电介质，这两种聚合物由具有宽带隙和大偶极矩的两种小分子组分合成。具有大分子量的双功能偶极玻璃不仅即使在10 wt%的高负载量下也能保持聚合物共混物的热稳定性，而且与任何单个组分相比，还能使极化和E大幅增强，在充放电效率为90%的情况下，实现了8.34 J/cm³（150°C）和6.21 J/cm³（200°C）的超高U。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/0da3/11455895/4235b38f770e/41467_2024_52791_Fig1_HTML.jpg

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通过协同优化偶极玻璃的带隙和极化来提高聚合物电介质的高温储能性能。

Enhanced high-temperature energy storage performances in polymer dielectrics by synergistically optimizing band-gap and polarization of dipolar glass.

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