All-organic dielectric polymer films exhibiting superior electric breakdown strength and discharged energy density by adjusting the electrode-dielectric interface with an organic nano-interlayer

Polymer dielectrics for energy storage applications usually endure high electric field strength. Adjustment of the composition and structure of the dielectric bulk phase to enhance the dielectric breakdown strength has been widely studied. However, the effect of electrode-dielectric interface on the breakdown strength has received little attention, which greatly hinders further development in this field. In this work, an all-organic double-layer dielectric film consisting of poly(vinylidene fluoride) (PVDF) as the matrix and polymethyl methacrylate (PMMA) as the organic nano-interlayer was prepared. By adjusting the electrode-dielectric interface, remarkably improved electric breakdown strength (767.05 MV m(-1)) and discharged energy density (19.08 J cm(-3)) were realized concurrently without sacrificing the charge-discharge efficiency. The experimental results and computational simulations reveal that the surface morphology of dielectrics has a great effect on the electric field distribution at the electrode-dielectric interface, and further affects the leakage current and breakdown strength of the dielectric. The PMMA nano-interlayer modifies the surface defects and increases the Young's modulus at the electrode-dielectric interface, leading to the improvement of insulation performance. These findings offer a new perspective to understand the impact of the electrode-dielectric interface on the polymer dielectric breakdown strength. This work provides a novel paradigm for fabricating polymer dielectrics with high breakdown strength for energy storage.

Automated summary

This work presents a novel paradigm for fabricating polymer dielectrics with high breakdown strength by adjusting the electrode-dielectric interface. The all-organic double-layer dielectric film achieved remarkably improved electric breakdown strength and discharged energy density without sacrificing the charge-discharge efficiency. Experimental results and computational simulations demonstrate the significant impact of dielectric surface morphology on the electric field distribution at the electrode-dielectric interface, highlighting the importance of PMMA nano-interlayer in enhancing insulation performance.