建立了适用于含孔隙NiTi合金中B2-R相变的相场模型,并用该相场模型研究了多孔NiTi合金中B2-R转变的微观组织演化过程以及孔隙率和孔尺寸对R相变体生长动力学行为的影响.多孔NiTi合金中R相变体以相互协调的方式形成"带状"的三维结构和"鱼骨"状的二维组织,变体之间形成的孪晶面包括{101}B2和{001}B2 2种,4组变体相交于〈010〉B2;这些结果与致密NiTi合金B2-R相变过程相同.多孔NiTi合金中R相优先在孔周围形核,且较大的孔周围有较多的变体形核;R相变体的平均尺寸随孔隙率增大而逐渐减小,随孔径增大而增加;相对于规则圆孔,不规则孔隙可导致R相变体尺寸略微减小;变体的尺寸均匀性则随孔隙率增大而提高,但对孔径大小和孔形状不敏感;孔隙数量越多且孔径越小,则B2-R转变越倾向于产生均匀而细密的R相组织.
参考文献
| [1] | Zhang Y P,Li D S,Zhang X P.Scr Mater,2007; 57:1020 |
| [2] | Bansiddhi A,Sargeant T D,Stupp S I,Dunand D C.Acta Biomater,2008; 4:773 |
| [3] | Kim J I,Li Y,Miyazaki S.Acta Mater,2004; 52:487 |
| [4] | Dautovich D P,Purdy G R.Can Metall Q,1965; 4:129 |
| [5] | Sandrock G D,Perkins A J,Hehemann R F.Metall Mater Trans,1971; 2B:2769 |
| [6] | Hwang C M,Meichle M,Salamon M B,WaymanC M.Philos Mag,1983; 47A:9 |
| [7] | Hwang C M,Meichle M,Salamon M B,WaymanC M.Philos Mag,1983; 47A:31 |
| [8] | Lin H C,Wu S K,Chou T S,Kao H P.Ada Metall Mater,1991; 39:2069 |
| [9] | Miyazaki S,Igo Y,Otsuka K.Ada Metall,1986; 34:2045 |
| [10] | Miyazaki S,Otsuka K.Metall Trans,1986; 17A:53 |
| [11] | Michutta J,Somsen C,Yawny A,Dlouhy A,Eggeler G.Ada Mater,2006; 54:3525 |
| [12] | Bataillard L,Bidaux J E,Gotthardt R.Philos Mag,1998; 78A:327 |
| [13] | Stroz D,Kwarciak J,Morawiec H.J Mater Sci,1988; 23:4127 |
| [14] | Allafi J K,Ren X,Eggeler G.Ada Mater,2002; 50:793 |
| [15] | Yuan B,Zhang X P,Chung C Y,Zhu M.Mater Sci Eng,2006; A438-440:585 |
| [16] | Wu S L,Liu X M,Chu P K,Chuang C Y,Chu C L,Yeung K W K.J Alloys Compd,2008; 449:139 |
| [17] | Wang Y,Khachaturyan A G.Ada Mater,1997; 45:759 |
| [18] | Khachaturyan A G.Theory of Structural Transformation in Solids.New York:Wiley-Interscience,1983:213 |
| [19] | Man J,Zhang J H,Rong Y H.Ada Metall Sin,2010; 46:775(满蛟,张骥华,戎咏华.金属学报,2010;46:775) |
| [20] | Artemev A,Wang Y,Khachaturyan A G.Ada Mater,2000; 48:2503 |
| [21] | Jin Y M,Artemev A,Khachaturyan A G.Ada Mater,2001; 49:2309 |
| [22] | Wang Y,Li J.Ada Mater,2010; 58:1212 |
| [23] | Ke C B,Ma X,Zhang X P.Acta Metall Sin,2010; 46:84 (柯常波,马骁,张新平.金属学报,2010;46:84) |
| [24] | Otsuka K,Ren X.Prog Mater Sci,2005; 50:511 |
| [25] | Miyazaki S,Wayman C M.Acta Metall,1998; 36:181 |
| [26] | Li D S,Zhang Y P,Zhang X P.J Alloys Compd,2009; 474:L1 |
| [27] | Wang Y U.Acta Mater,2006; 54:953 |
| [28] | Wang Y,Ren X,Otsuka K,Saxena A.Acta Mater,2008; 56:2885 |
| [29] | Man J,Zhang J H,Rong Y H.Appl Phys Lett,2010; 96:131904 |
| [30] | Bhattacharya K,Kohn R V.Acta Mater,1996; 44:529 |
| [31] | Wagner M F,Windl W.Acta Mater,2008; 56:6232 |
| [32] | Wang G,Xu D S,Ma N,Zhou N,Payton E J,Yang R,Mills M J,Wang Y.Acta Mater,2009; 57:316 |
| [33] | Shen C,Chen Q,Wen Y H,Simmons J P,Wang Y.Scr Mater,2004; 50:1023 |
| [34] | Shen C,Chen Q,Wen Y H,Simmons J P,Wang Y.Scr Mater,2004; 50:1029 |
| [35] | Wang Y,Banerjee D,Su C C,Khachaturyan A G.Acta Mater,1998; 46:2983 |
| [36] | Fukuda T,Saburi T,Doi K,Nenno S.Mater Trans JIM,1992; 33:271 |
| [37] | Ke C B,Ma X,Zhang X P.Acta Metall Sin,2010; 46:921(柯常波,马骁,张新平.金属学报,2010;46:921) |
| [38] | Ren X,Wang Y,Otsuka K,Lloveras P,Castan T,Porta M,Planes A,Saxena A.MRS Bull,2009; 34:838 |
| [39] | Ren X,Wang Y,Zhou Y M,Zhang Z,Wang D,Fan G,Otsuka K,Suzuki T,Ji Y,Zhang J,Tian Y,Hou S,Ding X D.Philos Mag,2010; 90:141 |
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