-Ray Irradiation Significantly Enhances Capacitive Energy Storage Performance of Polymer Dielectric Films

Polymer dielectric capacitors are fundamental in advanced electronics and power grids but suffer from low energy density, hindering miniaturization of compact electrical systems. It is shown that high-energy and strong penetrating gamma-irradiation significantly enhances capacitive energy storage performance of polymer dielectrics. gamma-irradiated biaxially oriented polypropylene (BOPP) films exhibit an extraordinarily high energy density of 10.4 J cm(-3) at 968 MV m(-1) with an efficiency of 97.3%. In particular, an energy density of 4.06 J cm(-3) with an ultrahigh efficiency of 98% is reliably maintained through 20 000 charge-discharge cycles under 600 MV m(-1). At 125 degrees C, the gamma-irradiated BOPP film still delivers a high discharged energy density of 5.88 J cm(-3) with an efficiency of 90% at 770 MV m(-1). Substantial improvements are also achieved for gamma-irradiated cycloolefin copolymers at a high temperature of 150 degrees C, verifying the strategy generalizability. Experimental and theoretical analyses reveal that the excellent performance should be related to the gamma-irradiation induced polar functional groups with high electron affinity in the molecular chain, which offer deep energy traps to impede charge transport. This work provides a simple and generally applicable strategy for developing high-performance polymer dielectrics.