Hybrid Al6060/TiB2/Microsilica Composites Produced by Ultrasonically Assisted Stir Casting and Radial-Shear Rolling: Microstructural Evolution and Strength–Ductility Balance
Abishkenov M. Tavshanov I. Lutchenko N. Nogayev K. Ashkeyev Z. Kulidan S.
November 2025Multidisciplinary Digital Publishing Institute (MDPI)
Eng
2025#6Issue 11
We report a scalable route to hybrid aluminum matrix composites (AMCs) based on Al6060 (as-fabricated condition) reinforced with 2 wt.% TiB2 and 1 wt.% microsilica, fabricated by ultrasonically assisted stir casting (UASC) followed by radial-shear rolling (RSR). Premixing and preheating of powders combined with acoustic cavitation/streaming during UASC ensured uniform, non-sedimentary particle dispersion and low-defect cast billets. X-ray diffraction of the as-cast composite shows fcc-Al with weak TiB2 reflections and no reaction products; microsilica remains amorphous. Electron microscopy and EBSD after RSR reveal full erasure of cast dendrites, fine equiaxed grains, weakened texture, and a high fraction of high-angle boundaries due to the concurrent action of particle-stimulated nucleation (micron-scale TiB2) and Zener pinning/Orowan strengthening (50–350 nm microsilica). Mechanical testing shows that, in the cast state—comparing cast monolithic Al6060 to the cast hybrid-reinforced composite—yield strength (YS) increases from 61.7 to 77.2 MPa and ultimate tensile strength (UTS) from 103.4 to 130.7 MPa, without loss of ductility. After RSR to Ø16 mm (cumulated true strain ≈ 0.893), the hybrid attains YS 101.2 MPa, UTS 150.6 MPa, and elongation ≈ 22.0%, i.e., comparable strength to rolled Al6060 (UTS 145.1 MPa) while restoring/raising ductility by ~9.7 percentage points. Microhardness follows the same trend, increasing from 50.2 HV0.2 to 73.1 HV0.2 when comparing the base cast condition with the rolled hybrid. The route from UASC to RSR thus achieves a favorable mechanical strength–ductility balance using an economical, eco-friendly oxide/boride hybrid reinforcement, making it attractive for formable AMC bar and rod products.
aluminum matrix composites (AMCs) , mechanical properties , microstructure , radial-shear rolling , ultrasonically assisted stir casting
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Department of Technological Machines and Transportation, Karaganda Industrial University, Temirtau, 101400, Kazakhstan
Core Facilities—Office the Provost, Nazarbayev University, Astana, 010000, Kazakhstan
Department of Technological Machines and Transportation
Core Facilities—Office the Provost
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