Pendant Group Functionalization of Cyclic Olefin for High Temperature and High-Density Energy Storage.
Stuti ShuklaChao WuAnkit MishraJunkun PanAaron P CharnayAshish KhomaneAjinkya DeshmukhJierui ZhouMadhubanti MukherjeeRishi GurnaniPragati RoutRiccardo CasaliniRampi RamprasadMichael D FayerPriya D VashishtaYang CaoGregory SotzingPublished in: Advanced materials (Deerfield Beach, Fla.) (2024)
High-temperature flexible polymer dielectrics are critical for high-power-density energy storage and conversion under harsh operating conditions. These types of dielectrics will need to simultaneously possess a high bandgap, dielectric constant and glass transition temperature - a substantial challenge when designing novel dielectric polymers. In this work, by varying halogen substituents of an aromatic pendant hanging off a bicyclic mainchain polymer, a class of high-temperature olefins with adjustable thermal stability are obtained, all with uncompromised large bandgaps. Halogens substitution of the pendant groups at para or ortho position of polyoxanorborneneimides (PONB) imparts it with tunable high glass transition temperature from ∼220 to 245 °C, while with also moderate dielectric constant of ∼ 2.8-3.0 and high breakdown strength of ∼625-800 MV/m. A high energy density of 7.1 J/cc at 200 °C is achieved with p-POClNB, representing the highest reported energy density among all-organic homo-polymer dielectrics. Molecular dynamic simulations and ultrafast infrared spectroscopy were used to probe the free volume element distribution and chain relaxations of the polymers to provide insights to the dielectric thermal properties. An increase in free volume element is observed with the change in the pendant group from fluorine to bromine at the para position; however, a decrease in free volume element is observed as we change the pendant group from fluorine to chlorine at the ortho position because of the steric hindrance. Overall, the dielectric constant and band gap remain stable while the glass transition temperature changes more obviously. Consequently, by proper designing the pendant groups, the thermal stability of PONB can be improved for harsh condition electrification. This article is protected by copyright. All rights reserved.