Microstructure and electrical properties of nano-scale SnO2 hydrothermally coated CCTO-based composite ceramics

The hydrothermal method was successfully applied in this article to prepare nano-scale SnO2 coated CCTO composite ceramics (CCTO/xSnO(2), X = 0, 0.1, 0.2, 0.3, 0.4). XRD, HRTEM, FESEM, EDS, XPS are systematically used to study the phase composition, surface structure, microstructure, composition distribution, and valence state of CCTO/SnO2 composite ceramics. Sintered at a high temperature of 1040C for 8 h, the prepared CCTO/ SnO2 composite ceramic has obtained a dense microstructure and an exceptionally colossal dielectric constant(epsilon r > 6.7x 10(5) at 25Hz, epsilon(r) > 8.1x 10(4) at 1 kHz). The impedance spectroscopy and FESEM confirmed that the CCTO/ SnO2 composite ceramics have the polarization behavior between grain boundaries on the micrometer scale and the polarization between nanocrystals on the nanometer scale. This nanoscale nanocrystalline barrier layers capacitor has become the primary source of the giant dielectric phenomenon of CCTO/SnO2 composite ceramics.

Automated summary

The hydrothermal method was used to prepare nano-scale SnO2 coated CCTO composite ceramics, and various analysis techniques were employed to study their surface structure and composition distribution. The sintered ceramics exhibited a dense microstructure and a remarkably high dielectric constant. It was found that polarization occurred at both the grain boundaries on the micron scale and the nanocrystals on the nanometer scale, which contributed to the giant dielectric phenomenon of the CCTO/SnO2 composite ceramics.