Dithioester-terminated copolymers with simultaneous high dielectric constant and breakdown strength for energy storage

High-energy storable polymer dielectrics are highly desirable and applicable for compact and efficient power electronic devices. However, existing polymer dielectrics suffer from either a low dielectric constant or a low breakdown strength and exhibit an extremely low energy density. Here, the reversible addition-fragmentation chain transfer polymerization and polyaddition polymerization techniques are combined to create a dithioester-terminated polythiourea (PTU)-based copolymer dielectric with an extraordinarily high energy density of 10.7 J/cm(3). The end-group functionalized copolymer significantly increases the dielectric constant from 6.0 to 7.6, which enhances the breakdown strength from 264 to 563 MV/m. The theoretical analysis from the proton nuclear magnetic resonance, atomic force microscope (AFM), and the dynamics of the polarization behaviors demonstrates conformational transitions between the two distinct trans/trans and cis/trans thioureas, along with the formation of polar PTU nanoregions. These result in a flexible polarization reorientation process and increased dielectric constant. Meanwhile, the density functional theory calculations for the electronic structures of the block copolymers indicate that the excellent breakdown strength of the end-group functionalized copolymer is attributed to strong charge trapping from the unique dithioesters. This work proposes a strategy to achieve a simultaneous high dielectric constant and breakdown strength toward excellent energy storage performances by end-group functionalization and composition modifications.

Automated summary

A high-energy storable polymer dielectric with an exceptionally high energy density of 10.7 J/cm(3) has been successfully synthesized by combining reversible addition-fragmentation chain transfer polymerization and polyaddition polymerization techniques. The end-group functionalized copolymer significantly enhances the dielectric constant and breakdown strength. The conformational transitions of the thiourea groups and the charge trapping from the unique dithioesters are the key factors responsible for the improved dielectric properties.