Recent progress in developing polymer nanocomposite membranes with ingenious structures for energy storage capacitors

Polymer nanocomposite dielectrics (PNDs) have attracted extensive attention due to their excellent mechanical flexibility, ultra-fast charge/discharge rate and low cost. However, conventional membrane processing methods, such as simple physical blending of polymer matrices and fillers, result in PNDs with insufficient energy densities. Recently, developing ingenious structures of membranes used as PNDs has emerged as an important approach to enhance their comprehensive properties. In this review, the recent progress in PNDs for energy storage capacitor applications are reviewed, with a particular focus on optimizing dielectric and energy storage performance through rational structural design of membrane. The effects of microstructural filler designs on dielectric and energy storage properties are discussed in detail, including core-shell structures, hierarchical structures, and other special structures. The preparation methods and performances of PNDs with different macroscopic designs are also systematically discussed. Finally, a brief summary along with some future perspectives on this important research arena are provided.

Automated summary

Polymer nanocomposite dielectrics (PNDs) have attracted extensive attention for their excellent mechanical flexibility, ultra-fast charge/discharge rate and low cost. However, conventional membrane processing methods result in PNDs with insufficient energy densities. The recent progress in optimizing dielectric and energy storage performance through rational structural design of membranes in PNDs for energy storage capacitor applications is reviewed, along with the effects of microstructural filler designs.