Refinement mechanism of in-situ Al4C3 particles on AZ91 magnesium alloys

Yanping Guo; Mingang Zhang; Yaxu Jin

doi:10.1007/s11595-014-0884-9

Journal of Wuhan University of Technology Materials Science Edition ›› 2014, Vol. 29 ›› Issue (1) : 154 -158. DOI: 10.1007/s11595-014-0884-9

Metallic Materials

Refinement mechanism of in-situ Al₄C₃ particles on AZ91 magnesium alloys

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Abstract

The effects of SrCO₃ on the microstructure of AZ91 magnesium alloy were investigated by OM, SEM, EDS, XRD and DTA analyses. The results show that AZ91 magnesium alloy with 1.0% SrCO₃ addition has the best refining effect at 730 ° for 20 min, the average size of the α-Mg grain in AZ91 matrix alloy is reduced from about 91 μm to 58 μm, with reduction of about 36%. Based on the analysis results of EDS, binding energy, and Gibbs free energy, it is evident that the grain is refined because of the generation of A1₄C₃ particles which can be used as the crystal nucleus of the magnesium alloy when SrCO₃ is added. Owing to the generation of A1₄C₃ in AZ91 magnesium alloy, the grain boundary is pined and the grain growth is inhibited. In the accession to the Al₄C₃, small subcooling temperature difference leads to the formation of fine grain microstructure in alloy melt. Fine grain microstructure in AZ91 alloy melt with the addition of SrCO₃ can be obtained on the condition of lower undercooling temperature according to the DTA analysis results.

Keywords

magneisum alloy / strontium carbonate / grain refinement / aluminium carbide

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Yanping Guo, Mingang Zhang, Yaxu Jin. Refinement mechanism of in-situ Al₄C₃ particles on AZ91 magnesium alloys. Journal of Wuhan University of Technology Materials Science Edition, 2014, 29(1): 154-158 DOI:10.1007/s11595-014-0884-9

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References

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[1]	Zuo Y B, Xia M X, Liang S M, . Grain Refinement of DC Cast AZ91D Mg Alloy by Intensive Melt Shearing[J]. Materials Science and Technology, 2011, 27(1): 101-107.

[2]	Friedrich H, Schumann S Research for a “New Age of Magnesium” in the Automotive Industry[J]. Journal of Materials Processing Technology, 2001, 117: 276-281.

[3]	Gao L, Liang S M, Chen R S, . Correlation of Recalescence with Grain Refinement of Magnesium Alloys[J]. Trans. Nonferrous Mer. Soc. China, 2008, 18: 288-291.

[4]	Tae W K, Jae S K A Study on Deburring of Magnesium Alloy[J]. International Journal of Precision Engineering and Manufacturing, 2010, 11(2): 189-194.

[5]	Kojima Y Platform Science and Technology for Advanced Magnesium Alloy[J]. Materials Science Forum, 2000, 350–351: 3-18.

[6]	Lahaie D J, Bouchard M Physical Modeling of the Deformation Mechanisms of Semisolid Bodies and a Mechanical Criterion for Hot Tearing[J]. Metallurgical and Materials Transacions B, 2001, 32(8): 697-673.

[7]	Jin Q L, Eom J P, Lim S G, . Grain Refining Mechanism of a Carbon Addition Method in a Mg-A1 Magnesium Alloy[J]. Scriptia Materialia, 2003, 49: 1 129-1 132.

[8]	David H, Ma Q, Mark A, . Grain Refinement of Magnesium Alloys[J]. Metallurgical and Materials Transactions A, 2005, 36(7): 1 669-1 679.

[9]	Xiao S X, Wang C Y, Chen T L The Application of the Discrect Variational Method in the Densiry Functional Theory to Chemistry and Materials Physics[M], 1998 Beijing Science Press

[10]	L Bramffit Bruce. The Effect of Carbide and Nitride Additions on the Heterogeneous Nucleation Behavior of Liquid Iron[J]. Metallurgical Transaction A, 1970, 1(7): 1 987-1 995.