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Thermodynamics basic and alloy phase evolution of Mg-Sn-Si alloy are studied. The results indicate that for Mg-Sn-Si alloy, the specific heat of alloy phase increases with temperature, and it changes quickly at low temperature while gently at high temperature. In the range of low temperature, its thermal expansion increases exponentially with the increase of temperature, and in the range of high temperature the thermal expansion increases linearly. In the two structures of Mg2 (Six, Sn1-x) and Mg2 (Snx,Si1-x) phases, the replacement position of Si or Sn is indefinite, they could be face-center location or vertex location. Under the conditions of conventional solidification, the range of values for x is fluctuant, for it is in nonequilibrium state: x values are around 0.25 and 0.75 for Mg2(Six, Sn1-x) and Mg2(Snx, Si1-x) structure, respectively. The generation temperature of Mg2 (Si, Sn) phase is quite high, it can be precipitated directly from liquid phase, or be transformed from Mg2Si. The generation temperature of Mg2(Sn, Si) phase is lower than that of Mg2(Si, Sn), and it can be precipitated only from the matrix, the initial precipitation temperature of Mg2(Sn, Si) tends to rise with Sn content increasing.
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Keywords:
- Mg-Sn-Si alloy /
- thermodynamics basic /
- alloy phase /
- crystallization process
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[21] Monkhorst H J, Pack J D 1976 Phys. Rev. B 13 518
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[1] Kang D H, Park S S, Kim N J 2005 Mater. Sci. Eng. A 413–414 556
[2] Prasad Y V, Rao K P, Hort N, Kainer K U 2010 Int. J. Mater. Res. 101 300
[3] Zhang J X, Gao A H, Zhang H L 2013 J. Functional Mater. 44 2659 (in Chinese) [张建新, 高爱华, 张洪良 2013 功能材料 44 2659]
[4] Guo Y F, Li R D, Liu G L 2009 Acta Phys. Sin. 58 3315 (in Chinese) [郭玉福, 李荣德, 刘贵立 2009 物理学报 58 3315]
[5] Zhang J X, Guo Y, Guo X F 2013 Foundry 62 235 (in Chinese) [张建新, 郭宇, 郭学锋 2013 铸造 62 235]
[6] Yang M B, Guo Y C, Li H L, Duan C Y, Zhang J 2013 Rare Metal Mater. Engineer. 42 1541
[7] Peng H, Wang C L, Li J C, Wang H C, Wang M X 2010 Acta Phys. Sin. 59 4123 (in Chinese) [彭华, 王春雷, 李吉超, 王洪超, 王美晓 2010 物理学报 59 4123]
[8] Wan D Q, Yu T 2012 Foundry 61 1135 (in Chinese) [万迪庆, 于田 2012 铸造 61 1135]
[9] Ren L, Guo X F, Ren F, Cui H B 2013 Foundry 62 1122 (in Chinese) [任磊, 郭学锋, 任昉, 崔红保 2013 铸造 62 1122]
[10] Li S H, Zhang C X, Guan S K, Wen C L, Tian H T, Yu W W, Meng H 2012 J. Mater. Sci. Engineer. 30 562 (in Chinese) [李少华, 张春香, 关绍康, 文春领, 田海棠, 于雯雯, 孟辉 2012 材料科学与工程学报 30 562]
[11] Zhang A S, Wan S Y 2012 Hot Work. Technol. 41 113 (in Chinese) [章爱生, 万盛耀 2012 热加工工艺 41 113]
[12] Hu J L, Tang C P, Zhang X M, Deng Y L 2013 Trans. Nonferrous Metals Soc. China 23 3161
[13] Tang S Q, Zhou J X, Tian C W, Yang Y S 2011 Trans. Nonferrous Metals Soc. China 21 1932
[14] Yu B H, Chen D 2011 Chin. Phys. B 20 030508
[15] Suresh K, Rao K P, Prasad Y V, Hort N, Kainer K U 2013 Trans. Nonferrous Metals Soc. China 23 3604
[16] Zhang G, Du J, Li W F, Dou Q, Cai T X 2013 J. Mater. Engineer. 4 81 (in Chinese) [张果, 杜军, 李文芳, 豆琦, 蔡添祥 2013 材料工程 4 81]
[17] Xu C J, Dai P, Tu T, Yu L, Zhang Z M, Wang J C 2013 Trans. Materi. Heat Treat. 34 83 (in Chinese) [徐春杰, 代盼, 屠涛, 余玲, 张忠明, 王锦程 2013 材料热处理学报 34 83]
[18] Kozlov A, Grobner J, Schmid R 2011 J. Alloys Compoun. 509 3326
[19] Jung I H, Kang D H, Park W J, Kim N J, Ahn S H 2007 Comput. Coupl. Phase Diagr. Thermochem. 31 192
[20] Zhang J X, Gao A H, Guo X F, Ren L 2013 Acta Phys. Sin. 62 178101 (in Chinese) [张建新, 高爱华, 郭学锋, 任磊 2013 物理学报 62 178101]
[21] Monkhorst H J, Pack J D 1976 Phys. Rev. B 13 518
[22] Blanco M A, Francisco E, Luana V 2004 Comput. Phys. Commun. 158 57
[23] Blanco M A, Martin P A, Francisco E, Recio J M, Franco R 1996 J. Molecul. Struct. Theochem. 368 245
[24] Florez M, Recio J M, Francisco E, Blanco M A 2002 Phys. Rev. B 66 144112
[25] Francisco E, Blanco M A, Sanjurjo G 2001 Phys. Rev. B 63 094107
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