提出了一种针对超细晶和纳米晶金属(主要是fcc金属)晶间断裂的微结构计算模型,即采用基于机制的应变梯度塑性(CMSG)理论描述晶粒内部材料塑性变形过程中的变形、强化和尺度效应;采用黏聚力界面模型来模拟晶界的滑移和分离现象,以及晶间裂纹的萌生和演化,直至晶间断裂导致的材料失效.利用该计算模型模拟了纳米晶Ni的拉伸实验过程,对纳米晶Ni宏观力学行为和晶间微裂纹萌生与扩展之间的关系进行了研究,验证了针对超细晶和纳米晶力学性能的计算模型的有效性;同时,模拟结果表明,非均匀塑性变形导致高应变梯度效应,晶粒塑性变形强化显著,使晶界主导的变形机制对纳米晶金属的整体力学性能产生重要影响.
参考文献
| [1] | Schiotz J,Vegge T,Di T F D,Jacobsen K W.Phys Rev,1999; 60B:971 |
| [2] | van Swygenhoven H,Caro A,Farkas D.Scr Mater,2001; 44:1513 |
| [3] | Yamakov V,Wolf D,Phillpot S R,Mukherjee A K,Gleiter H.Nat Mater,2004; 3:43 |
| [4] | Farkas D,van Swygenhoven H,Derlet P M.Phys Rev,2002; 66B:060101-1-4 |
| [5] | Cao A,Wei Y.Phys Rev,2007; 76B:024113 |
| [6] | Schiotz J,Di T D,Jacobsen K W.Nature,1998; 391:561 |
| [7] | Fleck N A,Hutchinson J W.Adv Appl Mech,1997; 33:295 |
| [8] | Huang Y,Qu S,Hwang K C,Li M,Gao H.Int J Plast,2004; 20:753 |
| [9] | Gao H,Huang Y,Nix W D,Hutchinson J W.J Mech Phys Solids,1999; 47:1239 |
| [10] | Needleman A.Int J Fract,1990; 40:21 |
| [11] | Camaeho G T,Ortiz M.Int J Solids Struct,1996; 33:2899 |
| [12] | Chandra N,Li H,Shet C,Ghonem H.Int J Solids Struct,2002; 39:2827 |
| [13] | Hutchinson J W,Ewns A G.Acta Mater,2000; 48:125 |
| [14] | Turon A,Camanho P P,Costa J,Davila C G.An Interface Damage Model for the Simulation of Delamination Under Variable-Mode Ratio in Composite Materials.NASA Langley Research Center,Hampton,NASA/TM-2004-213277 |
| [15] | Warner D H,Sansoz F,Molinari J F.Int J Plast,2006;22:754 |
| [16] | van der Sluis O,Schreurs P J G,Meijer H E H.Mech Mater,2001; 33:499 |
| [17] | Iesulauro E,Ingraffea A R,Arwade S,Wawrzynek P A.Fatigue Fract Meeh,2002; 33:1417 |
| [18] | Wei Y J,Anand L.J Mech Phys Solids,2004; 52:2587 |
| [19] | Wang N,Wang Z R,Aust K T,Erb U.Acta Metal Mater,1995; 43:519 |
| [20] | Zhu B,Asaro R J,Krysl P,Bailey R.Acta Mater,2005;53:4825 |
上一张
下一张
上一张
下一张
计量
- 下载量()
- 访问量()
文章评分
- 您的评分:
-
10%
-
20%
-
30%
-
40%
-
50%