Processing, Microstructures, and Mechanical Properties of Magnesium Matrix Composites: A Review

doi:10.1007/s40195-014-0161-0

Abstract

Abstract:

In the last two decades, light-weight magnesium matrix composites have been the hot issue of material field due to their excellent mechanical and physical properties, e.g., high-specific strength and modulus, good wear resistance, and damping capacity. As compared with aluminum matrix composites, magnesium matrix composites have merit in their specific weight and have wide applications in aerospace and aeronautical fields. Generally, the processing techniques for magnesium matrix composites can be categorized as conventional and special processing routes. In recent years, as a special processing route, metal melt infiltration into porous ceramic preform featured by its low cost and availability of high-volume fraction of reinforced ceramics have been receiving much attention. Thus, in this review, one emphasis was put on the description of this processing technique in association with the means to obtain good wettability, the prerequisite for this kind of processing method. Based on the recognized fact that there exist clean interface and bonding ability between ceramics and matrix metal, in-situ reaction synthesis is usually utilized to fabricate magnesium matrix composites. Therefore, the interfacial feature was also reviewed for the in-situ reaction synthesis. Characterizations of microstructures and various mechanical-physical properties were finally summarized for magnesium matrix composites including tensile response, wear resistance, creep behavior, and damping capacity.

Key words: Magnesium matrix composites, Processing, Microstructure, Mechanical properties, Wettability, Interface

Chen Liqing, Yao Yantao. Processing, Microstructures, and Mechanical Properties of Magnesium Matrix Composites: A Review[J]. Acta Metallurgica Sinica (English Letters), 2014, 27(5): 762-774.

Figures/Tables 17

Fig. 1 Schematic of fabricating magnesium matrix composites reinforced by submicron SiCp by stir casting [10, 11]

Fig. 2 Schematic of squeeze casting process to produce Mg2B2O5w + B4Cp reinforced hybrid or Mg2B2O5w reinforced singular AZ91D magnesium matrix composites [13]

Fig. 3 Schematic of fabricating B4Cp-reinforced magnesium matrix composites by powder metallurgy

Fig. 4 Definition of the contact angle

Fig. 5 Curves showing the infiltration distance of Mg melt versus Ti content under different heating temperatures for 120 min a, holding for different times at 973 K b for fabricating B4C/Mg composites by pressureless infiltration [23]

Fig. 6 Schematic of in-situ reactive infiltration process for fabricating magnesium matrix composites [26]

Fig. 7 Microstructures of M40J carbon fiber-reinforced Al-4.7 wt% Mg composites after 5 vol% NaOH solution etching in longitudinal a, transverse b sections [39]

Fig. 8 SEM micrograph of Mg2B2O5 whiskers a, optical image of the as-cast AZ91D-based composite with 50 vol% Mg2B2O5 whiskers b [40]

Fig. 9 Optical micrograph of the as-cast a, SEM image of the as-deformed b SiCp/AZ91 composites [41]

Fig. 10 SEM microstructure at low magnification a, high magnification b of the as-fabricated TiC/Mg composites synthesized at 1,073 K [26]

Fig. 11 TEM micrographs of interfacial reaction products with different morphologies: a block-like and granular; b rod-like and granular reaction products

Table 1 Density and room temperature tensile properties of AZ91 alloy and (TiB2 + TiC)/Mg composites [24]

Materials	Density (g/cm³)	Modulus (GPa)	0.2%YS (MPa)	UTS (MPa)	Ductility (%)
AZ91	1.81	45 ± 2	82 ± 3	233 ± 0	6.0 ± 0.5
Mg/(TiB₂ + TiC)	1.93	53 ± 2	95 ± 2	298 ± 2	2.4 ± 0.4

Fig. 12 Volumetric wear loss versus sliding cycles for (Al2O3)f/AM60 composites: a with different addition contents of Al2O3 fibers at 2.0 N; b under different loads for AM60-9% (Al2O3)f at 298 K [53]

Table 2 Wear mechanisms for each combination of sliding condition and magnesium-based pin material [7]

Sliding speed (m/s)	Load (N)	Pin material	Wear mechanisms
Sliding speed (m/s)	Load (N)	Pin material	Abrasion	Oxidation	Delamination	Adhesion	Softening/melting
0.2	10	MgAl	√√	√	√
	10	SiC_p/MgAl	√√	√	√√
	30	MgAl	√√		√√
	30	SiC_p/MgAl	√√	√	√√√
0.5	10	MgAl	√	√√	√√
	10	SiC_p/MgAl	√	√√√	√
	30	MgAl	√√		√√
	30	SiC_p/MgAl	√√	√	√√√
1	10	MgAl	√	√√	√√
	10	SiC_p/MgAl	√	√√√	√
	30	MgAl	√√		√√	√
	30	SiC_p/MgAl	√√	√	√√
2	10	MgAl	√√		√√	√
	10	SiC_p/MgAl	√	√√	√
	30	MgAl	√		√	√√	√
	30	SiC_p/MgAl	√		√	√√	√
5	10	MgAl	√		√	√√	√
	10	SiC_p/MgAl	√		√	√√	√
	30	MgAl					√√√
	30	SiC_p/MgAl	√				√√√

Fig. 13 Comparison of minimum creep rates in several base materials and Saffil fibers reinforced AS21 magnesium matrix composites at 523 K [57]

Fig. 14 Damping capacities of AZ91D and TiC/AZ91D composites: a with the vibration frequency; b with the strain amplitude; c at different temperatures [64]

Fig. 15 Damping mechanism according to dislocation movement [68]

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