Effect of phase composition on the crystal structure and microwave dielectric properties of ZnMg2TiO5 ceramics

IF 6.2 2区材料科学 Q1 MATERIALS SCIENCE, CERAMICS Journal of The European Ceramic Society Pub Date : 2024-09-26 DOI:10.1016/j.jeurceramsoc.2024.116944

Qianbiao Du , Zhicong Chen , Kun Wei , Jiaojiao Liu , Linzhao Ma , Hao Li

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Abstract

Novel microwave dielectric ceramics ZnMg₂TiO₅ were synthesized by traditional solid-state method. Crystal structure refinement, transmission electron microscopy (TEM), and Raman spectroscopy reveal the coexistence of a secondary phase, MgO, with the predominant cubic spinel phase (Fd-3m) in ZnMg₂TiO₅ ceramics. The ceramics with dense microstructures exhibit excellent microwave dielectric properties at 1260 °C: ε_r = 15.6, Q×f = 92,899 GHz (at 10.8 GHz), and τ_f = −56.9 ppm/°C. The content of MgO, driven by thermodynamic factors, influences significantly impact the microstructure and microwave dielectric properties of the ceramics, particularly inducing the generation of localized lattice distortions and the formation of dislocations. The ε_r follows the same trend as the molecular polarizability of the actual individual crystal cells. Notably, a near-zero τ_f (−7.4 ppm/°C) was realized by two-phase composites and excellent comprehensive properties were obtained (ε_r = 17.9, Q×f = 57,546 GHz).

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相组成对 ZnMg2TiO5 陶瓷晶体结构和微波介电性能的影响

采用传统固态法合成了新型微波介电陶瓷 ZnMg2TiO5。晶体结构细化、透射电子显微镜（TEM）和拉曼光谱显示，在 ZnMg2TiO5 陶瓷中，次生相 MgO 与主要的立方尖晶石相（Fd-3m）共存。这种具有致密微观结构的陶瓷在 1260 ℃ 下具有优异的微波介电性能：εr = 15.6，Q×f = 92,899 GHz（10.8 GHz 时），τf = -56.9 ppm/°C。在热力学因素的驱动下，氧化镁的含量对陶瓷的微观结构和微波介电性能产生了重大影响，特别是诱发了局部晶格畸变和位错的形成。εr的变化趋势与实际单个晶胞的分子极化率相同。值得注意的是，两相复合材料实现了接近零的τf（-7.4 ppm/°C），并获得了优异的综合性能（εr = 17.9，Q×f = 57,546 GHz）。

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来源期刊

Journal of The European Ceramic Society 工程技术-材料科学：硅酸盐

CiteScore

10.70

自引率

12.30%

发文量

863

审稿时长

35 days

期刊介绍： The Journal of the European Ceramic Society publishes the results of original research and reviews relating to ceramic materials. Papers of either an experimental or theoretical character will be welcomed on a fully international basis. The emphasis is on novel generic science concerning the relationships between processing, microstructure and properties of polycrystalline ceramics consolidated at high temperature. Papers may relate to any of the conventional categories of ceramic: structural, functional, traditional or composite. The central objective is to sustain a high standard of research quality by means of appropriate reviewing procedures.