Interfacial Characteristic of as-Deformed SiCp-Reinforced Magnesium Matrix Composite

doi:10.1007/s40195-014-0128-1

Abstract

Abstract:

The (submicron + micron) SiCp-reinforced magnesium matrix composite was fabricated by stir casting. After the application of forging and extrusion, the interface between SiCp and Mg in the composite was investigated by transmission electron microscopy. Results show that the interfacial characterization was different at the interfaces of micron-SiCp/Mg and submicron-SiCp/Mg. While most interfaces between micron-SiCp and Mg were clean, the precipitated Mg₁₇Al₁₂ phase as well as dispersedly distributed nano-MgO particles was observed at some interfaces. Unlike the interface between micron-SiCp and Mg, no interfacial reaction product was found at the interface between submicron-SiCp and Mg in the present study. Besides, the specific orientation relationships were found at the interfaces between submicron-SiCp and Mg, which was thought to have developed during hot deformation process. At the fracture surface of the composite, the microcracks were found at the interface between micron-SiCp and Mg, while the interfacial bonding between submicron-SiCp and Mg was very well.

Key words: Magnesium matrix composite, SiC particles, Interfaces, TEM

Kun Deng Kun, Chao Li Jian, Feng Fan Jian, Jun Wang Xiao, Wu Kun, She Xu Bing. Interfacial Characteristic of as-Deformed SiCp-Reinforced Magnesium Matrix Composite[J]. Acta Metallurgica Sinica (English Letters), 2014, 27(5): 885-893.

Figures/Tables 10

Fig. 1 SEM micrographs and XRD patterns of SiCp: a SEM micrograph of 0.2 μm SiCp [24]; b XRD pattern of 0.2 μm SiCp; c SEM micrograph of 10 μm SiCp [25]; d XRD pattern of 10 μm SiCp [25]

Fig. 2 SEM images of SiCp-reinforced magnesium matrix composite after hot extrusion: a lower magnification; b higher magnification

Fig. 3 Morphologies of M-SiCp by TEM a, S-SiCp by HREM b in the as-extruded composite

Fig. 4 TEM micrograph at the interface between M-SiCp and Mg a, electron diffraction pattern of secondary phase (Mg17Al12) along \( [1\overline{1} \overline{3} ] \) zone axis b

Fig. 5 TEM micrographs of the composite showing the morphology of secondary phases a, electron diffraction patterns of S-SiCp along [011] zone axis b, Mg17Al12 along \( [\overline{1} 13] \)zone axis c

Fig. 6 Secondary phases at the interface between M-SiCp and Mg: a morphology of secondary phases; b selected area diffraction indicates that secondary phases are nano-MgO particles; c HREM image of nano-MgO particle

Fig. 7 TEM images of interface between S-SiCp and Mg: a TEM morphology of interface; b HREM image of interface; c filtration image of Fig. 7b

Fig. 8 The Second orientation relationship between S-SiCp and Mg: a TEM morphology of the interface along axis zone [011] of S-SiCp; b HREM image of interface; c filtration image of Fig. 8b

Fig. 9 Optical micrographs of as-cast a, as-forged b, as-extruded c SiCp-reinforced magnesium matrix composites

Fig. 10 Fracture surfaces of the as-extruded SiCp-reinforced magnesium matrix composite: a lower magnification; b higher magnification

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