Ageing kinetics and precipitation hardening behavior of aluminum-silicon: A volume fractions examination approach

Okechukwu Thomas Onah 1, Samuel David Tommy 2, * and Obinna Nwankwo Nwoke 3

1 Department of Mechanical and Production Engineering, Enugu State University of Science and Technology, Agbani, Enugu State, Nigeria.
2 Works and Engineering Services, Akanu Ibiam Federal Polytechnic, Unwana, Ebonyi State, Nigeria.
3 Department of Mechatronics Engineering Technology, Akanu Ibiam Federal Polytechnic, Unwana, Ebonyi State, Nigeria.
 
Research Article
GSC Advanced Research and Reviews, 2024, 20(01), 074–087.
Article DOI: 10.30574/gscarr.2024.20.1.0243
Publication history: 
Received on 25 May 2024; revised on 01 July 2024; accepted on 04 July 2024
 
Abstract: 
This work examines the ageing kinetics and precipitation hardening behaviour of ferrosilicon-silicon carbide reinforced aluminium metal matrix composites (AMMCs) with particular focus on the influence of varying the percentage volume fractions (%Vf) of reinforcement, ageing temperature and time on the material’s behaviour. The investigation systematically analyzed different %Vf of silicon carbide (SiC) of the AMMCs fabricated using dual stir casting technique; to examine the ageing kinetics, precipitation hardening behaviour and their impacts on the material’s mechanical properties so as to identify optimal ageing conditions for maximizing the performance of the composites. Percentage volume fraction and distribution of SiC particulates within the microstructure significantly affected the ageing kinetics and precipitation hardening behaviour; as higher %Vf of reinforcement led to a pronounced hardening effect which enhanced composite’s hardness by 45.98% and the yield strength by 46.28%. The activation energy of diffusion of the material increased with higher %Vf of SiC from 3508.508 J/mol at 0%Vf of SiC to 9170.342 J/mol at 25%Vf of SiC. This observed increment in activation energy follows the complex and enhanced diffusion pathway of Al-Si atoms, resulting in higher activation energy for the sustenance of the diffusion processes. The acceleration to precipitation hardening dropped with corresponding increase in ageing time. Thus, the precipitates hardening ratio (R) decreased from 0.9 with 5%Vf of SiC to 0.6 with 25%Vf of SiC at 100  ageing temperatures. A 15-20 %Vf of SiC offered a good balance between accelerated ageing kinetics and manageable activation energy, providing efficient hardening without excessively high diffusion barriers.
 
Keywords: 
Ageing kinetics; Precipitation hardening; Activation energy of diffusion; Acceleration to precipitation; Reinforcement distribution; Enhanced mechanical properties; Aluminium-silicon
 
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