<div class="section abstract"><div class="htmlview paragraph">With the advancement of lightweight magnesium-based hybrid composites, are
potential for weight management applications. The liquid state stir cast process
is the best way to produce complex shapes and most industries are preferred.
However, the melting of magnesium alloy and achieving homogenous particle
distribution are the major challenges for the conventional stir-casting process,
and hot crack formation is spotted due to thermal variations. The main
objectives of the present research are to enhance the microstructural and
mechanical behaviour of magnesium alloy hybrid nanocomposite (AZ91E) adopted
with boron carbide (B<sub>4</sub>C) and alumina (Al<sub>2</sub>O<sub>3</sub>)
nanoparticles through a semisolid stir cast technique associated with inert
atmosphere helps to limits the oxide formation and reduce risk of magnesium
fire. The effect of composite processing and multiple reinforcements on surface
morphology, tensile strength, impact strength, and hardness were thoroughly
evaluated and compared. The results of surface morphology studies demonstrate
homogeneous particle dispersion with reduced casting defects. Furthermore, the
AZ91E alloy hybrid nanocomposite (HNC) exhibits superior tensile strength,
impact strength, and hardness when compared to the monolithic AZ91E alloy,
showcasing improvements of 18%, 23%, and 25%, respectively, which is suggested
for automotive seat frame applications.</div></div>