Novel high-entropy relaxors with ultrahigh energy-storage efficiency and density

One of the major problems in ceramic capacitors is that their limited energy storage density (W-rec) and efficiency restrict the development in cutting-edge energy storage applications. In this paper, the non-equimolar ratio high-entropy ceramics are designed using the "entropy" strategy based on the traditional ferroelectric BaTiO3. Ultimately, the superparaelectric region of BaTiO3 is extended successfully, forming the local polymorphic distortion structure and realizing the transformation of ferroelectrics-relaxor ferroelectrics. Here, the outstanding W-rec of 7.3 J/cm(3), the excellent xi of 214.71 J/kV center dot m(2), and the highest energy storage efficiency (eta = 94.3 %) in high-entropy ceramics are obtained under moderate electric fields, indicating a breakthrough progress in energy storage applications of high-entropy relaxor ferroelectrics. Additionally, our work compared performance across multiple dimensions using measurement parameters, giving readers a more comprehensive reference.