A high-temperature performing and near-zero energy loss lead-free ceramic capacitor

A pivotal obstacle of obtaining dielectric ceramics with large recoverable energy density (W-rec) and ultrahigh energy efficiency (eta) desperately needs to be overcome for the development of advanced energy storage devices for high pulsed power systems, especially via an environment-friendly lead-free method. Here we report a series of lead-free dielectric bulk ceramics for high-temperature energy storage capacitors with near-zero energy loss. Confirmed by aberration-corrected scanning transmission electron microscopy and phase-field simulation, a judiciously designed heterostructure in which rhombohedral and tetragonal polar nanoregions are embedded in a cubic paraelectric matrix was constructed. The combination of the increased breakdown strength and the minimized polarization hysteresis, respectively, based on the heterostructure design and repeated rolling process, contributes to a large W-rec of 10.28 J cm(-3) and a record-high eta of 97.11%, superior to the reported lead-free bulk ceramics. Based on such structure-induced advantages, the wide-temperature stability (25-200 degrees C) and high performance (W-rec similar to 6.35 +/- 9.1% J cm(-3), eta similar to 94.82% +/- 3.4%) of the dielectric ceramics broaden their application in high temperature energy storage systems. This work conspicuously contributes to the development of the next generation high-temperature capacitors and suggests a new paradigm that may stimulate the development of higher-performance energy storage dielectrics.

Automated summary

We successfully developed a series of lead-free dielectric ceramics for high-temperature energy storage capacitors with near-zero energy loss. The designed heterostructure embedding rhombohedral and tetragonal polar nanoregions in a cubic paraelectric matrix contributes to a large recoverable energy density of 10.28 J cm(-3) and a record-high energy efficiency of 97.11%. The wide-temperature stability (25-200 degrees C) and high performance (recoverable energy density of 6.35 +/- 9.1% J cm(-3), energy efficiency of 94.82% +/- 3.4%) of the dielectric ceramics broaden their application in high temperature energy storage systems.