Realizing superior energy storage properties in lead-free ceramics via a macro-structure design strategy

Abstract

Based on the principle of sustainable development theory, lead-free ceramics are regarded as an excellent candidate in dielectrics for numerous pulsed power capacitor applications due to their outstanding thermal stability and environmental friendliness. However, the recoverable energy storage density (W_rec) and energy storage efficiency (η) of most lead-free ceramics are less than 4 J cm⁻³ and 80%, respectively, due to their low electric breakdown strength (E_b), large remnant polarization (P_r) and/or small maximum polarization (P_max). In order to dramatically enhance the W_rec and η of lead-free ceramics, the macro-structure design strategy (construction of the ceramics with a sandwich structure comprising the large P_max of ferroelectrics as the outer layer and the large E_b of the linear-like dielectric as the middle layer) was adopted to synergistically optimize the polarization and E_b in this study. Interestingly, the prepared ceramics exhibited a clear sandwich structure and the ultra-high W_rec of 6.78 J cm⁻³, together with a very high η of 89.7%, could be achieved at a high electric field of 572 kV cm⁻¹, which are superior to the previously reported lead-free ceramics. Meanwhile, the energy storage properties also exhibited outstanding stability. In particular, the η was higher than 86% and the variation of W_rec was less than ±3% within 1–100 Hz and 30–120 °C. Therefore, the founding of this study opened up a novel and efficient guideline for exploring new environmentally friendly ceramics with superior energy storage properties.