High‐temperature dielectric polymers are in constant demand for the multitude of high‐power electronic devices employed in hybrid vehicles, grid‐connected photovoltaic and wind power generation, to name a few. There is still a lack, however, of dielectric polymers that can work at high temperature (> 150 °C). Herein, a series of all‐organic dielectric polymer composites have been fabricated by blending the n‐type molecular semiconductor 1,4,5,8‐naphthalenetetracarboxylic dianhydride (NTCDA) with polyetherimide (PEI). Electron traps are created by the introduction of trace amounts of n‐type small molecule semiconductor NTCDA into PEI, which effectively reduces the leakage current and improves the breakdown strength and energy storage properties of the composite at high temperature. Especially, excellent energy storage performance is achieved in 0.5 vol.% NTCDA/PEI at the high temperatures of 150 and 200 °C, e.g., ultrahigh discharge energy density of 5.1 J cm−3 at 150 °C and 3.2 J cm−3 at 200 °C with high discharge efficiency of 85–90%, which is superior to its state‐of‐the‐art counterparts. This study provides a facile and effective strategy for the design of high‐temperature dielectric polymers for advanced electronic and electrical systems.

Superior High‐Temperature Energy Density in Molecular Semiconductor/Polymer All‐Organic Composites

Flexible barium titanate@polydopamine/polyvinylidene fluoride/polymethyl methacrylate nanocomposite films with high performance energy storage

Nanoscale Grain Sizes in BNT-based Ceramics with Superb Energy Storage Performances via Coating Boron Nitride Nanosheets

Sintering behavior, phase composition, microstructure, and dielectric characteristics of garnet-type Ca3Fe2Ge3O12 microwave ceramics

Synthesis and characterization of phase pure and Mg-modified AgZnVO4 microwave dielectrics for high-frequency ULTCC applications

Outstanding discharge energy density and efficiency of the bilayer nanocomposite films with BaTiO3-dispersed PVDF polymer and polyetherimide layer

Broadband and high-efficiency of garnet-typed ceramic dielectric resonator antenna for 5G/6G communication application

Enhanced Breakdown strength and Electrostatic Energy Density of Polymer Nanocomposite Films Realized by Heterostructure ZnO-ZnS Nanoparticles

Importance of uniformity of grain size to reduce dc degradation and improve reliability of ultra-thin BaTiO3-based MLCCs

Elaborately designed polymer dielectric films with low Coefficient of Thermal Expansion demonstrating high and stable electrostatic energy density over a wide temperature range

Rong Sun

Papers

Outstanding discharge energy density and efficiency of the bilayer nanocomposite films with BaTiO3-dispersed PVDF polymer and polyetherimide layer

Broadband and high-efficiency of garnet-typed ceramic dielectric resonator antenna for 5G/6G communication application

Enhanced Breakdown strength and Electrostatic Energy Density of Polymer Nanocomposite Films Realized by Heterostructure ZnO-ZnS Nanoparticles

Importance of uniformity of grain size to reduce dc degradation and improve reliability of ultra-thin BaTiO3-based MLCCs

Elaborately designed polymer dielectric films with low Coefficient of Thermal Expansion demonstrating high and stable electrostatic energy density over a wide temperature range