Journal
MATERIALS RESEARCH BULLETIN
Volume 161, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.materresbull.2023.112157
Keywords
BaTiO3; Ceramics; Energy storage; Relaxor ferroelectric; Breakdown strength
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Recently, dielectric ceramic materials have been explored to enhance the energy density and efficiency of high-power capacitors. In this study, the (1-x) [0.88BaTiO3-0.12Bi(Li0.5Nb0.5)O3]-x(0.8BaTiO3-0.2SrTiO3) ceramics were designed for improved dielectric temperature stability and breakdown strength. The influence of composition and phase structure on dielectric properties was investigated, and improvements in dielectric properties and energy storage performance were achieved. The 0.95[0.88BaTiO3-0.12Bi(Li0.5Nb0.5)O3]-0.05 (0.8BaTiO3-0.2SrTiO3) ceramic showed the best performance with an energy storage density of 2.88 J/cm3 (efficiency -86.81%) under 320 kV/cm. This work not only provides key materials for the next generation of high-end energy storage capacitors, but also suggests a new route for optimizing the performance of other relaxor ferroelectrics.
Recently, dielectric ceramic materials have been widely explored for high-power capacitors applications. However, it is still challenged for capacitors to enhance the energy density and efficiency. Here, the (1-x) [0.88BaTiO3-0.12Bi(Li0.5Nb0.5)O3]-x(0.8BaTiO3-0.2SrTiO3) (0.05 <= x <= 0.20) ceramics were designed to improve both dielectric temperature stability and breakdown strength. Influence of composition and phase structure on dielectric properties were studied in detail. Improvement of both dielectric properties and energy storage performance was achieved in this work. The 0.95[0.88BaTiO3-0.12Bi(Li0.5Nb0.5)O3]-0.05 (0.8BaTiO3-0.2SrTiO3) ceramic shows the best performance, with an energy storage density up to 2.88 J/cm3 (We -2.51 J/cm3) and a high efficiency -86.81% under 320 kV/cm. This work not only provides key materials for the next generation of high-end energy storage capacitors, but also suggests a different route for optimizing the performance of other relaxor ferroelectrics.
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