Litcius/Paper detail

Enhanced strength–ductility synergy of SiC particles reinforced aluminum matrix composite via dual configuration design of reinforcement and matrix

Lichaoran Guan, He Cao, Yishi Su, Di Zhang, Kan Liu, Andong Hua, Yahui Peng, Haitao Zhao, Qiubao Ouyang

2024Materials & Design45 citationsDOIOpen Access PDF

Abstract

To overcome the strength-ductility conflict in particle reinforced aluminum matrix composites (PRAMCs), a novel dual configuration strategy of microstructure was proposed in this work. The dual configuration including both heterogeneous grain structure and hybrid reinforcements was obtained by powder metallurgy, which was designed as submicron-sized SiC particles (SiCsm)/Al and micron-sized SiC particles (SiCm)/2024Al components. Representative alternating coarse grain (CG) bands containing SiCm and ultra fine grain (UFG) bands with dispersed SiCsm were revealed in microstructural characterizations. Compared to corresponding homogeneous composites with the same fraction particles, the dual configuration composite achieved simultaneous enhancement in strength and ductility and remained a comparable Young’s modulus of 98GPa, which represented 442 MPa in yield strength, 590 MPa in ultimate strength and 8.7 % in fracture elongation. The extra strength provided by hetero-deformation induced (HDI) strengthening is a potential dominant strengthening mechanism. The intrinsic toughening mechanisms primarily contribute to HDI strain hardening and enhanced dislocation accumulation capacity, while the extrinsic toughening mechanisms presumably attribute to more uniform microcrack distribution and blunting effect of CG zones on cracks. Our work provides a feasible route including ball milling and powder assembly to preparate high-modulus aluminum matrix composites for strength-ductility balance design.

Topics & Concepts

Materials scienceComposite materialDuctility (Earth science)Strengthening mechanisms of materialsComposite numberMicrostructureWork hardeningPowder metallurgyVolume fractionStrain hardening exponentUltimate tensile strengthNanocompositeSpecific strengthModulusCreepAluminum Alloys Composites PropertiesAdvanced ceramic materials synthesisMicrostructure and mechanical properties