TiO2-assisted Mg-Ti-O-based ceramics improve thermal conductivity and microwave dielectric properties by modifying the microstructure

IF 2.6 4区材料科学 Q2 MATERIALS SCIENCE, CERAMICS

Journal of Electroceramics Pub Date : 2024-11-27 DOI:10.1007/s10832-024-00379-5

Xinyan Liu, Yuanxun Li, Fuyu Li

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Abstract

The influence of TiO₂ on the crystal phase, microstructure, thermal conductivity, and microwave dielectric properties of Mg-Ti-O-based ceramics during sintering are explored. XRD analysis reveals that doped TiO₂ completely reacts with Mg₂TiO₄ to generate MgTiO₃, and (1-y)Mg₂TiO₄ + yMgTiO₃ ceramics are obtained. The undoped TiO₂ samples exhibit an excessively large grain size with an uneven grain size distribution and numerous pores. The reaction between TiO₂ and Mg₂TiO₄ effectively reduces the grain size of Mg₂TiO₄ to a reasonable range, thereby facilitating the mitigation of internal defects within grains. Additionally, the formation of MgTiO₃ results in a microstructure characterized by two phases with staggered distribution and mutual inhibition. This phenomenon aids in controlling the growth and arrangement of grains, ultimately filling pores and enhancing ceramic density. A reasonable grain size and regular arrangement are advantageous for improving the thermal and dielectric performance of ceramics compared to excessively larger grains and uneven distribution. Mg-Ti-O-based ceramics contribute to an enhancement in thermal conductivity to 10.1 W/(m·K) and in Q×f value to 143,046 GHz.

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tio2辅助mg - ti基陶瓷通过改变微观结构来改善其导热性和微波介电性能

探讨了TiO2在烧结过程中对mg - ti基陶瓷的晶相、微观结构、导热性能和微波介电性能的影响。XRD分析表明，掺杂TiO2与Mg2TiO4完全反应生成MgTiO3，得到（1-y）Mg2TiO4 + yMgTiO3陶瓷。未掺杂的TiO2样品晶粒尺寸过大，晶粒分布不均匀，孔隙众多。TiO2与Mg2TiO4的反应有效地将Mg2TiO4的晶粒尺寸减小到合理范围，从而有利于缓解晶粒内部缺陷。此外，MgTiO3的形成导致了两相交错分布和相互抑制的微观结构。这种现象有助于控制晶粒的生长和排列，最终填充孔隙，提高陶瓷密度。相对于晶粒过大和分布不均匀，合理的晶粒尺寸和规则的排列有利于提高陶瓷的热性能和介电性能。mg - ti基陶瓷的导热系数提高到10.1 W/(m·K)， Q×f值提高到143,046 GHz。

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来源期刊

Journal of Electroceramics 工程技术-材料科学：硅酸盐

CiteScore

2.80

自引率

5.90%

发文量

审稿时长

5.7 months

期刊介绍： While ceramics have traditionally been admired for their mechanical, chemical and thermal stability, their unique electrical, optical and magnetic properties have become of increasing importance in many key technologies including communications, energy conversion and storage, electronics and automation. Electroceramics benefit greatly from their versatility in properties including: -insulating to metallic and fast ion conductivity -piezo-, ferro-, and pyro-electricity -electro- and nonlinear optical properties -feromagnetism. When combined with thermal, mechanical, and chemical stability, these properties often render them the materials of choice. The Journal of Electroceramics is dedicated to providing a forum of discussion cutting across issues in electrical, optical, and magnetic ceramics. Driven by the need for miniaturization, cost, and enhanced functionality, the field of electroceramics is growing rapidly in many new directions. The Journal encourages discussions of resultant trends concerning silicon-electroceramic integration, nanotechnology, ceramic-polymer composites, grain boundary and defect engineering, etc.