Aiqin Wang scite author profile

Aiqin Wang

2Publications

1Citation Statement Received

71Citation Statements Given

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Henan University of Science and Technology

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Microstructure evolution and strengthening mechanism of A356 composites reinforced with micron and nano SiCp

Song

Wang²,

Ma³

et al. 2022

Mater. Res. Express

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The single scale SiCp reinforcement has a limited effect on the comprehensive performance of the composite, which restricts the optimization and improvement of its comprehensive performance. In order to improve the material's strong plasticity, wear resistance, thermal expansion and other properties of the comprehensive requirements. The (micron and nano) dual-scale SiCp/A356 composites with different volume fractions were prepared using the combination of powder metallurgy and hot extrusion. The effects of different volume fractions of dual-scale SiCp (15, 20, 25, 30 vol.%) on the microstructure and mechanical properties of A356 composites were studied, and the strengthening mechanism of dual-scale SiCp/A356 composites was analyzed. The results show that with the increasing of dual-scale SiCp content, the distribution uniformity and mechanical properties of SiCp first increase and then decrease. When the content of dual-scale SiCp is 25%, the mechanical properties reach their maximum values, with the hardness, yield strength and tensile strength of 112.3 HBW, 228 MPa and 310 MPa, respectively. They are improved by 86.9%, 81.0%, 74.2% as compared with those of A356 alloy, respectively. The fracture modes of dual-scale SiCp/A356 composites are mainly Al matrix tearing and SiCp fracture. The main strengthening mechanism is Orowan strengthening, along with thermal mismatch strengthening, load transfer strengthening and fine grain strengthening.

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Effect of Al₂Cu constituent layer thickness discrepancy on the tensile mechanical behavior of Cu/Al₂Cu/Al layered composites: a molecular dynamics simulation

et al. 2023

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Nano-polycrystalline Cu/Al2Cu/Al layered composites with different layer thicknesses d of single-crystal Al2Cu constituent are constructed. The effects of d on the strength and fracture modes of nano-polycrystalline Cu/Al2Cu/Al layered composites are systematically investigated by molecular dynamics (MD) simulations. The uniaxial tensile results show that the ultimate strength and fracture mode of the nano-polycrystalline Cu/Al2Cu/Al layered composites do not change monotonically with the change of single crystal Al2Cu constituent layer thickness d, the ultimate strength peaking at d=2.44 nm, and the toughness reaching the optimum at d=4.88 nm. The improvement of deformation incompatibility between Cu, Al and Al2Cu components increases the ultimate strength of polycrystalline Cu/Al2Cu/Al laminated composites. Due to the high activity of Cu dislocation and the uniformity of strain distribution of single crystal Al2Cu, the fracture of nano-crystalline Cu/Al2Cu/Al layered composites changes from brittleness to toughness. This study is crucial to establish the organic connection between microstructure and macroscopic properties of Cu/Al layered composites. To provide theoretical basis and technical support for the application of Cu/Al layered composites in high-end fields, such as automotive and marine, aerospace and defense industries.

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Aiqin Wang

Microstructure evolution and strengthening mechanism of A356 composites reinforced with micron and nano SiCp

Effect of Al₂Cu constituent layer thickness discrepancy on the tensile mechanical behavior of Cu/Al₂Cu/Al layered composites: a molecular dynamics simulation

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Aiqin Wang

Microstructure evolution and strengthening mechanism of A356 composites reinforced with micron and nano SiCp

Effect of Al2Cu constituent layer thickness discrepancy on the tensile mechanical behavior of Cu/Al2Cu/Al layered composites: a molecular dynamics simulation

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Effect of Al₂Cu constituent layer thickness discrepancy on the tensile mechanical behavior of Cu/Al₂Cu/Al layered composites: a molecular dynamics simulation