采用显微压痕方法研究了Si、Ge、GaAs和InP四种半导体单晶的变形与断裂行为.通过测量[100]取向单晶体面内的显微硬度,裂纹开裂的临界压痕尺寸以及断裂韧性,分析了这四种材料力学性能的面内各向异性行为.结果表明:在压痕载荷的作用下,Si和Ge的塑性变形以剪切断层为主,而GaAs和InP则通过滑移系的开动协调变形.[100]取向的Si、Ge、GaAs和InP四种单晶的面内显微硬度、弹性模量和断裂韧性表现出不同程度的各向异性.裂纹长度与压痕尺寸间的关系表明,与GaAs和InP相比,Si、Ge具有较小的临界压痕尺寸和拟合直线斜率,这一临界压痕尺寸和拟合直线斜率的变化规律分别与材料的硬度和断裂韧性的变化规律一致.
参考文献
| [1] | K.E.Petersen,Silicon as a mechanical material,Processding of the IEEE,70,420(1982) |
| [2] | S.Adachi,GaAs,AlAs,and AlzGal-xAsB:Material parameters for use in research and device applications,J Appl Phys,58,R1(1985) |
| [3] | I.Yonenaga,U.Onose,K.Sumino,Mechanical properties of GaAs crystals,J.Mater.IRes.,2,252(1987) |
| [4] | T.P.Pearsall,Properties,Processing and Applications of Indium Phosphide,New EMIS Proceedings Series,(London,INSPEC,1999) p.68 |
| [5] | S.M.Spearing,Materials issues in microelectromechanical systems (MEMS),Acta Mater,48,179(2000) |
| [6] | S.Koubalti,J.J.Couderc,C.Levade,G.Vanderschaeve,Photoplastic effect and Vickers microhardness in Ⅲ-Ⅴ and Ⅱ-Ⅳ semiconductor compounds,Mater Sci and Eng A,234-236,865(1997) |
| [7] | R.Navamathavan,D.Arivuoli,G.Attolini,C.Pelosi,C.K.Choi,Mechanical properties of some binary,ternary and quaternary Ⅲ-Ⅴ compound semiconductor alloys,Physica B:Condensed Matter,392,51(2007) |
| [8] | S.Wang,P.Pirouz,Mechanical properties of undoped GaAs.Ⅲ:Indentation experiments,Acta Mater,55,5526(2007) |
| [9] | G.M.Pharr,Measurement of mechanical properties by ultra-low load indentation,Mater.Sci.and Eng.A,253,151(1998) |
| [10] | I.Yonenaga,Mechanical Properties and Dislocation Dynamics in Ⅲ-Ⅴ Compounds,J.Phys.Ⅲ,7,1435(1997) |
| [11] | I.Yonenaga,T.Suzuki,Indentation hardnesses of semiconductors and a scaling rule,Philos.Mag.Lett.,82,535(2002) |
| [12] | E.Le Bourhis,G.Patriarche,Plastic deformation of Ⅲ-Ⅴ semiconductors under concentrated load,Progress in Crystal Growth and Characterization of Materials,47,1(2003) |
| [13] | L.J.Vandeperre,F.Giuliani,S.J.Lloyd,W.J.Clegg,The hardness of silicon and germanium,Acta Mater,6307(2007) |
| [14] | A.Kailer,Y.G.Gogotsi,K.G.Nickel,Phase transformations of silicon caused by contact loading,J Appl Phys,81,3057(1997) |
| [15] | F.Cleri,S.Yip,D.Wolf,S.R.Phillpot,Atomic-scale mechanism of crack-tip plasticity:Dislocation nucleation and crack-tip shielding,Phys.Rev.Lett.,79,1309(1997) |
| [16] | R.Perez,P.Gumbsch,Directional anisotropy in the cleavage fracture of silicon,Phys.Rev.Lett.,84,5347(2000) |
| [17] | F.Ebrahimi,L.Kalwani,Fracture anisotropy in silicon single crystal,Mater Sci and Eng A,268,116(1999) |
| [18] | R.F.Cook,Strength and sharp contact fracture of silicon,J Mater Sci,41,841(2006) |
| [19] | J.J.Wortman,R.A.Evans,Young's Modulus,Shear Modulus,and Poisson's Ratio in Silicon and Germanium,J Appl Phys,36,153(1965) |
| [20] | Y.T.Cheng,C.M.Cheng,Relationships between hardness,elastic modulus,and the work of indentation,Appl Phys Lett,614(1998) |
| [21] | Y.T.Cheng,C.M.Cheng,Scaling,dimensional analysis,and indentation measurements,Mater Sci and Eng R,91(2004) |
| [22] | K.Zeng,E.Soderlund,A.E.Giannakopoulos,D.J.Rowcliffe,Controlled indentation:A general approach to determine mechanical properties of brittle materials,Acta Mater,44,1127(1996) |
| [23] | B.R.Lawn,A.G.Evans,D.B.Marshall,Elastic/Plastic Indentation Damage in Ceramics:the Median/Radial Crack System,J.Am.Ceram.Soc.,63,574(1980) |
| [24] | B.R.Lawn,E.R.Fuller,Equilibrium penny-like cracks in indentation fracture,J.Mater.Sci.,10,2016(1975) |
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%