Influences of crystallization temperature on the structure, dielectric, and energy storage characteristics of KBaSrNb5O15-based glass-ceramics

Glass-ceramics capacitors have great application potential in pulsed power systems, due to ultrafast discharge speed and high dielectric breakdown strength (BDS). Here, lead-free niobate glass-ceramic dielectric materials were synthesized, and the effects of heat treatment temperature on the dielectric, ferroelectric, and energy storage properties of glass-ceramics were investigated comprehensively. The results exhibit that the dielectric permittivity first increases and then decreases as the crystallinity increases; however, the dielectric BDS diminishes. At the optimum crystallization temperature of 740 degrees C, the maximum value of discharge energy density is 2.2 J/cm(3) at 600 kV/cm, which is about 7.6 times that of mother glass. Furthermore, an ultrahigh power density of about 380.9 MW/cm(3) and ultrafast discharge speed of about 11.2 ns were achieved simultaneously. Meanwhile, great thermal stability of charge-discharge property was verified in this glass-ceramics. According to P-E loops and dielectric test result, a high dielectric constant (similar to 207) and low dielectric loss (<0.005) as well as high energy storage efficiency of about 94.9% were achieved for G740 sample. The previous results make the obtained glass-ceramic as potential candidates in dielectric capacitors.

Automated summary

Glass-ceramic dielectric materials with lead-free niobate were synthesized and their properties were studied. The results showed that at the optimum crystallization temperature, the glass-ceramics exhibited high discharge energy density, power density, dielectric constant, and low dielectric loss.