Improving the sintering performance and dielectric properties of thermally conductive low-temperature co-fired alumina by controlling the firing atmosphere

IF 2.2 4区材料科学 Q2 MATERIALS SCIENCE, CERAMICS

Journal of Asian Ceramic Societies Pub Date : 2022-07-03 DOI:10.1080/21870764.2022.2099514

Koichi Shigeno, Takumi Nagata, H. Fujimori

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Abstract

ABSTRACT Here, we focused on the firing atmosphere to promote low-temperature sintering and enhance the dielectric properties of low-temperature co-fired alumina (LTCA) containing 5 wt.% of CuO–TiO2–Nb2O5–Ag2O as the sintering aid. Controlling the oxygen partial pressure (pO2) to form Ag–Cu–Ti–Nb–O-based complex oxides and lowering the melting temperature of the sintering aid are necessary to improve the sinterability. Moreover, controlling the pO2 such that AgNbO3 disappears is important to improve the dielectric properties of LTCA. A dense sintered body with approximately 95% relative density was obtained by firing an LTCA sample for 2 h at a firing temperature of 900°C and pO2 of 0.02 atm, and its dielectric properties were measurable. The thermal conductivity of 17 W/mK was better than that of conventional low-temperature co-fired ceramics (2–7 W/mK). These results provide important guidelines for low-temperature sintering and producing LTCA with enhanced dielectric properties.

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控制烧结气氛改善导热低温共烧氧化铝的烧结性能和介电性能

摘要在这里，我们重点研究了烧结气氛，以促进低温烧结，并提高含有5 wt.%CuO–TiO2–Nb2O5–Ag2O作为烧结助剂的低温共烧氧化铝（LTCA）的介电性能。控制氧分压（pO2）以形成Ag–Cu–Ti–Nb–O基复合氧化物并降低烧结助剂的熔融温度对于提高烧结性是必要的。此外，控制pO2使得AgNbO3消失对于改善LTCA的介电性能是重要的。通过在900°C的烧制温度和0.02atm的pO2下烧制LTCA样品2小时，获得了相对密度约为95%的致密烧结体，并且其介电性能是可测量的。17 W/mK的热导率优于传统低温共烧陶瓷（2–7 W/mK）。这些结果为低温烧结和生产具有增强介电性能的LTCA提供了重要的指导。

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来源期刊

Journal of Asian Ceramic Societies Materials Science-Ceramics and Composites

CiteScore

5.00

自引率

4.30%

发文量

审稿时长

10 weeks

期刊介绍： The Journal of Asian Ceramic Societies is an open access journal publishing papers documenting original research and reviews covering all aspects of science and technology of Ceramics, Glasses, Composites, and related materials. These papers include experimental and theoretical aspects emphasizing basic science, processing, microstructure, characteristics, and functionality of ceramic materials. The journal publishes high quality full papers, letters for rapid publication, and in-depth review articles. All papers are subjected to a fair peer-review process.