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Improved microwave dielectric characteristics in CaHf <sub>1−</sub> <i> <sub>x</sub> </i> Ti <i> <sub>x</sub> </i> O <sub>3</sub> ceramics

Xi Wang, Jun Zuo Shi, Xiao Li Zhu, Lei Li, Xiang Ming Chen

2022Journal of the American Ceramic Society14 citationsDOI

Abstract

Abstract In the present work, effects of Ti‐substitution for Hf upon microwave dielectric characteristics for CaHfO 3 ceramics were investigated. CaHf 1− x Ti x O 3 solid solution in space group Pnma was determined in the present ceramics with x = 0–0.075, and only minor amount of secondary phases of CaHfO 3 ( R , 1.3 wt%) and Ca 2 Hf 7 O 16 ( R , 0.8 wt%) was detected. The significantly improved microwave dielectric characteristics were achieved with Ti‐substitution in CaHfO 3 ceramics. With increasing x , the temperature coefficient of resonant frequency τ f was substantially tuned from negative to positive through zero, which was caused by the decrease of oxygen octahedral tilting, and the Qf value was apparently improved simultaneously and reached the maximum of 43670 GHz at x = 0.025, while the dielectric constant ε r increased monotonously. The remarkable improvement of Qf was attributed to the enhancement of octahedral framework rigidity and the decreased nonuniform distribution of inner chemical bonding in crystal based on the change of chemical bond parameters calculated by the Phillips–Van Vechten–Levine bond theory, which was further confirmed by the higher frequency and narrower width of stretch mode of octahedron (i.e., A 1g (O) near 730 cm −1 ) in Raman spectra. An interesting phenomenon was found in titanium‐containing perovskite ceramics that they had consistent trend of τ f changing with tolerance factor, which was helpful to design temperature‐stable perovskite microwave dielectric ceramics. The best combination of microwave dielectric characteristics was achieved at x = 0.035: ε r = 27.2, Qf = 42 870, and τ f = +3 ppm/°C. For practical applications of the present ceramics, further improvement of Qf is required, and it is expected to be achieved through microstructure optimization.

Topics & Concepts

OctahedronCeramicDielectricMaterials scienceTemperature coefficientAnalytical Chemistry (journal)MicrowavePerovskite (structure)Raman spectroscopyCrystal structureMineralogyCrystallographyChemistryOpticsMetallurgyComposite materialPhysicsQuantum mechanicsOptoelectronicsChromatographyMicrowave Dielectric Ceramics SynthesisFerroelectric and Piezoelectric MaterialsLayered Double Hydroxides Synthesis and Applications