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In-depth characterization of FSP-enhanced aluminum metal matrix: A study in materials modeling and computational techniques

Adedotun Adetunla, Esther T. Akinlabi, Tien‐Chien Jen

2024Journal of Materials Research and Technology12 citationsDOIOpen Access PDF

Abstract

The production of aluminum metal-matrix composites (AMM) involves reinforcing aluminum and its alloys with various powders, with the addition of ceramic reinforcements expected to enhance mechanical properties, corrosion resistance, and wear resistance. However, suboptimal production techniques often result in reduced ductility and toughness when incorporating non-deformable ceramic reinforcements. To address this, friction stir processing (FSP) was employed as a novel surface modification process, using Ti–6Al–4V particles to reinforce 1100 Aluminum Alloy. Microstructures of the composites were analyzed through scanning electron microscopy (SEM), revealing a mean particle size of 2.69 × 103μm for a one-pass FSP at X155 magnification. Notably, the two-pass sample with a particle size of 2.69 × 103μm displayed fewer spherical structures and more irregular structures, indicating a change in the flow mechanism. The three-pass sample exhibited a mean particle size of 1.36 × 103μm, indicating a more uniform distribution and significant size reduction compared to one and two passes. Additionally, a torque-based predicted heat-input analysis indicated that higher temperatures resulting from increased heat production rate and power input led to a decrease in torque with rising rotational speed. The threaded taper tool generated more heat, potentially facilitating plastic deformation. Finite element analysis using ABAQUS predicted how this heat affected composite quality, closely aligning with experimental data, with less than a 10 °C difference between processing temperatures in experimental and simulated data. The peak temperature increased as the tool rotated at various tool speeds in line with the projected temperature history of FSP.

Topics & Concepts

Materials scienceFriction stir processingCeramicComposite materialMetal matrix compositeMicrostructureParticle sizeDuctility (Earth science)Rotational speedParticle (ecology)Friction stir weldingAluminiumScanning electron microscopeDeformation (meteorology)Grain sizeAlloyMetallurgyCreepMechanical engineeringOceanographyPhysical chemistryChemistryGeologyEngineeringAluminum Alloys Composites PropertiesAdvanced Welding Techniques AnalysisMXene and MAX Phase Materials