Microstructure and thermal properties of binary ceramic particle-reinforced aluminum matrix composites with SiC/LAS

Multiphase particle-reinforced strategy shows promise for efficiently improving the comprehensive properties of aluminum matrix composites (AMCs) such as thermophysical and mechanical properties. In this work, AMC reinforced with β -eucryptite (LAS), and silicon carbide (SiC) particles were successf...

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Bibliographic Details
Published in:Journal of materials science 2022, Vol.57 (3), p.1796-1809
Main Authors: Zhang, Shihao, Hou, Qinglin, Fu, Zhixiang, Zhang, Weili, Jiang, Haiyun
Format: Article
Language:English
Subjects:
Aluminum
Aluminum base alloys
Aluminum matrix composites
Analysis
Bonding strength
Ceramic matrix composites
Characterization and Evaluation of Materials
Chemistry and Materials Science
Classical Mechanics
Composites & Nanocomposites
Crystallography and Scattering Methods
Eucryptite
Forging
Grain size
Interfacial bonding
Materials Science
Mechanical properties
Metal products
Microstructure
Particulate composites
Polymer Sciences
Powder metallurgy
Powders
Residual stress
Silicon carbide
Silicon compounds
Solid Mechanics
Tensile stress
Thermal expansion
Thermal properties
Thermodynamic properties
Thermophysical properties
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Summary:Multiphase particle-reinforced strategy shows promise for efficiently improving the comprehensive properties of aluminum matrix composites (AMCs) such as thermophysical and mechanical properties. In this work, AMC reinforced with β -eucryptite (LAS), and silicon carbide (SiC) particles were successfully prepared via a powder forging process. The microstructure morphology, interface compatibility, and coefficient of thermal expansion (CTE) of these composites were evaluated. Microstructural characterization illustrated that the co-effect of SiC and LAS resulted in a discontinuous phase with a microporous and deformation-free structure. The microporous structure of these composites was conducive for inward expansion and the elimination of internal stress, effectively limiting the outward thermal expansion behavior of the Al alloys. Moreover, SiC and LAS exhibited tight interfacial bonds with the Al grains, enhancing interfacial bonding strength. These composites provided practical and robust tensile stress that limited the thermal expansion of the Al matrix under heating. A fine Al grain size (53.5 nm) and low micro-strain (0.4 × 10 –4 ) were obtained with increasing LAS content. Consequently, the composites achieved a low CTE of 17.27 × 10 –6  K −1 at 500 °C. The experimental CTE values were also compared with theoretical values calculated by a rule of mixture model to confirm that the excellent interfacial bonding between the LAS and SiC reinforcements and the Al matrix imposed an effective constraint on matrix expansion. Graphical abstract
ISSN:0022-2461
1573-4803
DOI:10.1007/s10853-021-06639-x