High-temperature BaTiO <sub>3</sub>-based ceramic capacitors by entropy engineering design
Yan Song, Min Zhang, Shun Lan, Bingbing Yang, Yiqian Liu, Ce‐Wen Nan, Yuanhua Lin
Abstract
High-performance BaTiO<sub>3</sub>(BTO)-based dielectric ceramics have great potential for high-power energy storage devices. However, its poor temperature reliability and stability due to its low Curie temperature impedes the development of most electronic applications. Herein, a series of BTO-based ceramics are designed and prepared on the basis of entropy engineering. Owing to the incorporation of Bi(Mg<sub>0.5</sub>Ti<sub>0.5</sub>)O<sub>3</sub>, relaxation behavior and low dielectric loss at high temperatures have been achieved. Moreover, the high-entropy strategy also promotes lattice distortion, grain refinement and excellent resistance, which together increase the breakdown field strength. These simultaneous effects result in outstanding energy storage performance, ultimately achieving stable energy density (<i>U</i><sub>e</sub>) of 5.76 J·cm<sup>−3</sup> and efficiency (<inline-formula id="M2"> <math id="mathml_M2" display="inline" overflow="scroll"><mi>η</mi></math></inline-formula>) of 89%. Most importantly, the outstanding temperature stability makes high-entropy BTO-based ceramics realize a significant energy storage density of 4.90<inline-formula id="M3"> <math id="mathml_M3" display="inline" overflow="scroll"><mo>±</mo></math></inline-formula>0.14 J·cm<sup>−3</sup> with the efficiency above 89%, spanning a wide temperature range of 25–250 °C, as well as cycling reliability with negligible performance deterioration after 3<inline-formula id="M5"> <math id="mathml_M5" display="inline" overflow="scroll"><mo>×</mo></math></inline-formula>10<sup>5</sup> cycles at 300 kV∙cm<sup>−1</sup> and 200 °C. This research presents an effective method for designing temperature-stable and reliable dielectrics with comprehensive energy storage performance.