Combustion synthesis of high-performance high-entropy dielectric ceramics for energy storage applications

High-entropy dielectric ceramics have demonstrated a promising prospect for applications in energy storage recently. However, most high-entropy dielectrics synthesized by conventional solid-state reaction (SSR) method demonstrated unsatisfactory performance for energy storage. Therefore, it is meaningful to develop a feasible way to fabricate high-performance high-entropy dielectric ceramics. Herein, high-entropy (Sr0.6Bi0.2Na0.2)(Ti1-xZrx/2Alx/4Nbx/4)O3 ceramics are prepared by a solution combustion synthesis (SCS) method. The SCS fabricated ceramics (x = 0.25) demonstrate a high recoverable energy density of-4.46 J/cm3 at a high critical electric field of 520 kV/cm, a high energy efficiency -88.52%, a large power density of -176.65 MW/cm3 (at 400 kV/cm), an ultrafast discharge time of-48 ns, and a high Vikers hardness of-7.09 GPa. The key energy storage parameters are much better than those of the samples prepared by the SSR method owing to the absence of unexpected impurity phases, and the refined grain size at the submicrometer scale in our SCS fabricated high-entropy ce-ramics. The study provides a facile way to fabricate high-performance high-entropy dielectric ceramics for en-ergy storage, indicating that the SCS routine is notably advantageous for preparing high-entropy dielectric energy ceramics.