期刊
CERAMICS INTERNATIONAL
卷 48, 期 18, 页码 25826-25832出版社
ELSEVIER SCI LTD
DOI: 10.1016/j.ceramint.2022.05.257
关键词
Negative thermal expansion; Aluminium matrix composite; Interface control; High strength
资金
- National Natural Science Foundation of China [52071117, 52111530297]
- Inter Governmental S&T Cooperation Proposal
- Heilongjiang Provincial Science Fund for Distinguished Young Scholars [JQ2021E002]
- Heilongjiang Province Science Foundation [LH2020E030]
- Heilongjiang Touyan Innovation Team Program
The salient feature of low-expansion metal matrix composites is their dimensional stability. By using anti-perovskite manganese nitrogen compound as a thermal expansion inhibitor, high mechanical strength low-expansion composites have been successfully fabricated. The effects of fabricating temperature on the microstructure, thermal expansion, and mechanical properties of the composites have been discussed.
The salient feature of low-expansion metal matrix composites is their dimensional stability. Due to the limitation of the performance of the reinforcement, the current low-expansion metal matrix composite materials cannot achieve both low expansion and high mechanical strength at the same time. With its extremely negative thermal expansion behavior and metallic characteristics, the anti-perovskite manganese nitrogen compound can be used as an ideal thermal expansion inhibitor to prepare high mechanical strength low-expansion composite materials. In the present work, fully-dense Mn3.2Zn0.5Sn0.3N/Al composites with low thermal expansion and high strength have been successfully fabricated by pressure infiltration. The effects of fabricating temperature on the microstructure, thermal expansion and mechanical properties of the Mn3.2Zn0.5Sn0.3N/Al composites have been discussed. Several interfacial reactions were caused by the high fabrication temperature (750 degrees C and 800 degrees C). Lower fabrication temperature (700 degrees C) was used to obtain a well-controlled interface composite with low thermal expansion (alpha = 6.5 x 10(-6) K-1), high compression strength (481 MPa) and hardness (612 HV). A modified theoretical model has also been used to analyze the thermal expansion behavior of the composites.
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