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温度梯度对晶粒生长行为影响的相场模拟

魏承炀 李赛毅

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温度梯度对晶粒生长行为影响的相场模拟

魏承炀, 李赛毅

Effect of temperature gradient on grain growth behavior from phase field simulations

Wei Cheng-Yang, Li Sai-Yi
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  • 利用相场法建立了一个可应用于研究温度梯度影响下的晶粒生长行为的二维模型,模拟了多晶材料退火过程中由温度梯度引起的非均匀晶粒生长和定向晶粒生长行为.结果表明:退火过程中,在静态温度梯度的影响下,体系的晶粒呈现不均匀生长,且从晶粒生长指数来看,不同程度地偏离了正常晶粒生长;在动态温度梯度的影响下,体系内部常出现柱状晶粒生长,柱状晶粒前端持续生长至温度最高位置;柱状晶粒生长与动态热源的移动速率密切相关,只有当动态热源的移动速率处于最小和最大晶粒生长速率之间时,柱状晶粒才会出现.
    A 2D model is developed to investigate the grain growth behavior under the influence of temperature gradient using the phase field method. The model is used to simulate the effect of temperature gradient on the nonuniform and directional grain growth behavior during annealing of polycrystalline materials. The results show that the static temperature gradient leads to the nonumiform grain growth, and that the grain growth exponent deviates from that of normal grain growth. In the case of annealing with a moving temperature gradient, the columnar grains may develop towards the locations with the highest temperature in the heated zone. Moreover, the grain growth behavior is closely related to the moving speed of the moving heated zone. Columnar grains occur only when the moving speed of the heated zone is higher than the minimum grain growth rate but lower than the maximum grain growth rate.
    • 基金项目: 教育部新世纪优秀人才支持计划(批准号:NCET-06-0741)资助的课题.
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    Doherty R D, Hughes D A, Humphreys F J, Jonas J J, Juul Jensen D, Kassner M E, King W E, McNelley T R, McQueen H J, Rollett A D 1997 Mater. Sci. Eng. A 238 219

    [2]

    Humphreys F J, Hatherly M 2004 Recrystallization and related annealing phenomena (second edition) (Oxford: Elsevier) pp121-167

    [3]
    [4]
    [5]

    Li J, Johns S L, Iliescu B M, Frost H J, Baker I 2002 Acta Mater. 50 4491

    [6]

    Baker I, Li J 2002 Acta Mater. 50 805

    [7]
    [8]

    Rollett A D, Srolovitz D J, Anderson M P 1989 Acta Mater. 37 1227

    [9]
    [10]
    [11]

    Holm E A, Zacharopoulos N, Srolovitz D J 1998 Acta Mater. 46 953

    [12]
    [13]

    Simmons J P, Wen Y H, Shen C, Wang Y Z 2003 Mater. Sci. Eng. A 365 136

    [14]

    Chen L Q 1995 Scripta Metall. Mater. 32 115

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    [16]

    Li J J, Wang J C, Yang G C 2008 Chin. Phys. B 17 3516

    [17]
    [18]
    [19]

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    [20]
    [21]

    Lu Y, Beckermanm C, Ramirez J C 2005 J. Crys. Grow. 280 320

    [22]
    [23]

    Moelans N 2006 Ph. D. Dissertation (Leuven: Katholieke Universiteit Leuven)

    [24]

    Yang H, Zhang Q G, Chen M 2005 Acta Phys. Sin. 54 3740 (in Chinese) [杨 弘、张清光、陈 民 2005 54 3740]

    [25]
    [26]

    Moelans N, Blanpain B, Wollants P 2008 Phys. Rev. Let. 101 025502

    [27]
    [28]

    Kazaryan A, Wang Y, Dregia S A, Patton B R 2002 Acta Mater. 50 2491

    [29]
    [30]

    Chan J W, Hilliard J E 1958 J. Chem. Phy. 28 258

    [31]
    [32]
    [33]

    Encyclopedia Britannica (Encyclopedia Britannica, Inc., Chicago, IL)

    [34]

    Zong Y P, Wang M T, Guo W 2009 Acta Phys. Sin. 58 S161 (in Chinese) [宗亚平、王明涛、郭 巍 2009 58 S161]

    [35]
    [36]
    [37]

    Chen L Q, Shen J 1998 Comput. Phys. Commun. 108 147

    [38]

    Fan D, Chen L Q, Chen S P 1997 Mater. Sci. Eng. A 238 78

    [39]
    [40]
    [41]

    Chen Q, Ma N, Wu K S, Wang Y Z 2004 Scripta Mater. 50 471

    [42]

    Wei C Y, Gao Y J, Zhang L N 2008 Chin. J. Nonfer. Metal. 18 132 (in Chinese) [魏承炀、高英俊、张丽娜 2008 中国有色金属学报 18 132]

    [43]
    [44]
    [45]

    Grest G S, Anderson M P 1988 Phys. Rev. B 38 4752

    [46]
    [47]

    Anderson M P, Srolovitz D J, Grest G S, Sahni P S 1984 Acta Metal. 32 783

    [48]

    Song X Y, Liu G Q, He Y Z 1998 Prog. Natur. Sci. 8 337 (in Chinese) [宋晓艳、刘国权、何宜柱 1998 自然科学进展 8 337]

    [49]
    [50]

    Chen D Q, Zheng Z Q, Liu Z Y, Li S C 2003 Acta Metall. Sin. 39 1238 (in Chinese) [陈大钦、郑子樵、刘祖耀、李世晨 2003 金属学报 39 1238]

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出版历程
  • 收稿日期:  2010-07-31
  • 修回日期:  2011-01-11
  • 刊出日期:  2011-05-05

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