This research explored AA 6351reinforced with varying amounts of nano silicon carbide (five wt%) and nanoZirconia powder (3to 9 in steps of three wt%) composites' wear performance using the powder metallurgy technique. Wear tests were conducted on the specimens in a dry, ambient environment utilizing a tribometer(pin-on-disc). The impact of three factors – Zirconia wt percentage, load, and sliding velocity - on the wear rate and friction coefficient was investigated. An experimental design based on the Taguchi-nine-level orthogonal array was employed, allowing for efficient analysis of parameter significance. Optimum conditions for minimum wear were identified through a main effect plot, indicating 9% wt reinforcement, 1.34m/s sliding velocity, and 10 N load. Sliding velocity emerged as the primary determinant of wear- rate in the ANOVA analysis, followed by the contributions of reinforcement and load. Optimization for the lowest friction coefficient, again via the main effect plot, pointed to 9% wt reinforcement, 30 N load, and 0.84m/s sliding velocity. ANOVA showed that reinforcement strongly influenced friction, with sliding velocity and load playing more minor roles.This investigation identified the optimal conditions for producing AA 6351 composites with minimal wear and friction using the powder metallurgy method and varying amounts of nano silicon carbide and nano zirconia powder.