Investigation on Mechanical and Wear Properties of ZE43 Magnesium Composites Reinforced with Silicon Nitride by Friction Stir Processing

“…[68] Note: For RZ5 Fe, Cu, Mn, Ni, Si < 0.005. Moorthy et al [67] produced ZE43/Si 3 N 4 surface composites by friction stir processing and investigated the microstructure of the samples by SEM (Figure 10). The uneven size of the particles on the composite surfaces was attributed to their crushing with increasing heat during the stirring process.…”

“…The large difference between the thermal expansion coefficient of the matrix and the reinforcement particles causes the formation of geometrically necessary dislocations (GNDs) and improves the hardness and mechanical properties [60,62,83]. For surface composites produced by FSP, the hardness increase is attributed to grain size reduction, quench hardening and annealing [67]. Some researchers reported that an increase in reinforcement content increases the hardness up to critical content and then decreases the hardness.…”

“…In another example, the hardness of AZ31 alloy increased from 61 to 92 with 2 wt.% B 4 C addition [44]. The maximum hardness value was noted to be 122 HV for ZE43/18Si 3 N 4 composite [67]. The increase in hardness in composite materials can be attributed to the following reasons.…”

Tribological aspects of magnesium matrix composites: A review of recent experimental studies

“…[68] Note: For RZ5 Fe, Cu, Mn, Ni, Si < 0.005. Moorthy et al [67] produced ZE43/Si 3 N 4 surface composites by friction stir processing and investigated the microstructure of the samples by SEM (Figure 10). The uneven size of the particles on the composite surfaces was attributed to their crushing with increasing heat during the stirring process.…”

“…The large difference between the thermal expansion coefficient of the matrix and the reinforcement particles causes the formation of geometrically necessary dislocations (GNDs) and improves the hardness and mechanical properties [60,62,83]. For surface composites produced by FSP, the hardness increase is attributed to grain size reduction, quench hardening and annealing [67]. Some researchers reported that an increase in reinforcement content increases the hardness up to critical content and then decreases the hardness.…”

“…In another example, the hardness of AZ31 alloy increased from 61 to 92 with 2 wt.% B 4 C addition [44]. The maximum hardness value was noted to be 122 HV for ZE43/18Si 3 N 4 composite [67]. The increase in hardness in composite materials can be attributed to the following reasons.…”

Tribological aspects of magnesium matrix composites: A review of recent experimental studies

“…To study erosion resistance and relate it to several mechanical properties of neat materials and their hybrid composites, researchers have carried out effective tests [29]. Overall, an ideal erosion-resistant material should have an elevated surface area/volume ratio, high hardness, high adhesive strength, small filler size, and a good dispersion of filler; these characteristics result in better mechanical properties, namely scratch resistance and high ductility without strength loss, as presented in Figure 2.…”

“…To study erosion resistance and relate it to several mechanical properties of neat materials and their hybrid composites, researchers have carried out effective tests [29]. Deformation brought on by erodents is linked with elevated strain rates of approximately 10 5 -10 6 s −1 ; therefore, predicting stress conditions is difficult and correlating mechanical properties with erosion rates is also very complicated.…”

Anti-Wear and Anti-Erosive Properties of Polymers and Their Hybrid Composites: A Critical Review of Findings and Needs

Enhancement in Tribological Characteristics of Friction Stir Processed AZ91D Alloy Composite Reinforced with Molybdenum Disulfide