Multiscale dislocation dynamics analyses of laser shock peening in silicon single crystals

International Journal of Plasticity

Volumn 22, Issue 12, 2006, Pages 2171-2194

  Cheng, G J ^a   Shehadeh, M A ^a  

^a Washington State University   (United States)

Author keywords

3D dislocation dynamics; Brittle materials; Laser shock peening; Multiscale simulation; Silicon

Indexed keywords

BRITTLENESS; COMPUTER SIMULATION; DISLOCATIONS (CRYSTALS); LASER APPLICATIONS; MICROSTRUCTURE; SILICON;

3D DISLOCATION DYNAMICS; LASER SHOCK PEENING; MULTISCALE DISLOCATION DYNAMICS PLASTICITY (MDDP); MULTISCALE SIMULATION;

SINGLE CRYSTALS;

EID: 33747791404     PISSN: 07496419     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijplas.2006.03.006     Document Type: Article

References (48)

1. Alexander H., and Haasen P. Solid State Phys. 22 (1968) 27
2. Berthe L., Fabbro R., Peyre P., and Bartnicki E. Wavelength dependent of laser shock-wave generation in the water-confinement regime. J. Appl. Phys. 8 (1999) 7552-7555
3. Cai W., Bulatov V.V., Justo J.F., Argon A.S., and Yip S. Intrinsic mobility of a dissociated dislocation in silicon. Phys. Rev. Lett. 8 15 (2000) 3346
4. Cheng, G.J., Pirzada, D., 2005a. Mechanical property enhancement of silicon component with laser shock peening, In: TMS 2005, 137th Annual Meeting and Exhibition, San Francisco, CA, February 13-17, 2005.
5. Cheng G.J., and Shehadeh M. Dislocation behavior in silicon crystal by laser shock peening: a multiscale simulation approach. Scr. Mater. 53 9 (2005) 1013-1018
6. Clauer, A.H. et al. 1981. Effects of laser induced shock waves on metals. In: Shock Waves and High Strain Phenomena in Metals-Concepts and Applications. Plenum, New York, 675-702.
7. Devaux D., Fabbro R., Tollier L., and Bartnicki E. J. Appl. Phys. 7 4 (1993) 2268
8. Devincre, B., 1996. Meso-scale simulation of the dislocation dynamics. In: Kirchner, H.O. et al. (Eds.), Computer Simulations in Materials Science, pp. 309-323.
9. Domnich V., Gogotsi Y., and Dub S. Appl. Phys. Lett. 76 (2000) 2214
10. Fabbro R., Fournier J., Ballard P., Devaux D., and Virmont J. Physical study of laser-produced plasmas in confined geometry. J. Appl. Phys. 68 2 (1990) 775-784
11. Fruhauf J., Gartner E., and Jansch E. Silicon as a plastic material. J. Micromech. Microeng. 9 (1999) 305
12. Gartner E., Frdhauf J., Loschner U., and Emer H. Laser bending of etched silicon microstructures. Microsyst. Technol. 7 1 (2001) 23
13. Gerberich W.W., Mook W.M., Cordill M.J., Carter C.B., Perrey C.R., Heberlein J.V., and Girshick S.L. Reverse plasticity in single crystal silicon nanospheres. Int. J. Plasticity 21 12 (2005) 2391-2405
14. Ghoniem N., and Sun L.Z. Fast-sum method for the elastic field of three-dimensional dislocation ensembles. Phys. Rev. B 60 1 (1999) 128-140
15. Hirth J.P., and Lothe J. Theory of Dislocations (1982), Krieger Publishing Company, Malabar, FL
16. Hirth J.P., Rhee M., and Zbib H.M. J. Computer Aided Mater. Des. 3 (1996) 164-166
17. Huff, M.A., Nikolich A.D., Schmidt, M.A., 1991, A threshold pressure switch utilizing plastic deformation of silicon. In: IEEE Transducers '91, Technical Digest, p. 177.
18. Khan S.M.A., Zbib H.M., and Hughes D.A. Modeling planar dislocation boundaries using multi-scale dislocation dynamics plasticity. Int. J. Plasticity 20 6 (2004) 1059-1092
19. Khraishi T.A., Yan L., and Shen Y.L. Dynamic simulations of the interaction between dislocations and dilute particle concentrations in metal-matrix composites (MMCs). Int. J. Plasticity 20 6 (2004) 1039-1057
20. Kubin L.P., Canova G., Condat M., Devincre B., Pontikis, and Brechet Y. Dislocation microstructures and plastic flow: a 3D simulation. Solid State Phenomena 23 and 24 (1992) 455-472
21. Lawn B. Fracture of Brittle Solids (1975), Cambridge University Press, Cambridge and New York p. 249.
22. Loveridge-Smith A., Allen A., Belak J., et al. Anomalous elastic response of silicon to uniaxial shock compression on nanosecond time scales. Phys. Rev. Lett. 86 11 (2001) 2349-2352
23. Mann A.B., Heerden D.v., Pethica J.B., and Weihs T.P. Size-dependent phase transformations during point loading of silicon. J. Mater. Res. 15 (2000) 1754
24. Minor A.M., Lilleodden E.T., Jin M., Stach E.A., Chrzan D.C., and Morris J.W. Room temperature plasticity in silicon. Philos. Mag. 85 (2005) 323-330
25. Minor A.M., Lilleodden E.T., Jin M., Stach E.A., Chrzan D.C., and Morris J.W. Room temperature dislocation plasticity in silicon. Philos. Mag. 8 2-3 (2005) 323-330
26. Needleman A. Computational mechanics at the mesoscale. Acta Mater. 48 (2000) 105-124
27. Patel J.R., and Chaudliurie A.R. Macroscopic plastic properties of dislocation free germanium and other semiconductor crystals. J. Appl. Phys. 3 9 (1963) 2788
28. Pearson G.L., Read W.T., and Feldmann W.L. Deformation and fracture of small silicon crystals. Acta Metall. 5 (1957) 181-191
29. Peyre P., Scherpereel X., Berthe L., and Fabbro R. Current trends in laser shock processing. Surf. Eng. 1 5 (1998) 377-380
30. Pharr G.M., Oliver W.C., and Harding D.S. J. Mater. Res. 6 (1991) 1129
31. Rabier, and Demenet. Low temperature high stress plastic deformation of semiconductors: the silicon case. Phys. Stat. Sol. (b) 222 63 (2000) 63-74
32. Rhee M., Zbib H.M., Hirth J.P., Huang H., and de la Rubia T. Models for long/short-range interactions and cross slip in 3D dislocation simulation of bcc single crystals. Modeling Simul. Mater. Sci. Eng. 6 (1998) 467-492
33. Schwarz K.W., and LeGoues F.K. Dislocation patterns in strained layers from sources on parallel glide planes. Phys. Rev. Lett. 79 (1997) 1877-1880
34. Shehadeh M.A., Zbib H.M., and Diaz de la Rubia T. Multiscale dislocation dynamics simulations of shock compression in copper single crystal. Int. J. Plasticity 2 12 (2005) 2369-2390
35. Siethoff H. Recovery processes in the high-temperature deformation of germanium, silicon, and indium antimonide. J. Phys. C 4 (1983) 217-225
36. Siethoff H., Ahlborn K., and Schroeter W. Two independent mechanisms of dynamical recovery in the high-temperature deformation of silicon and germanium. Philos. Mag. A 5 1 (1984) L1-L6
37. Sumino K. Handbook on Semiconductors (1994), North-Holland, Amsterdam and New York
38. Van der Giessen E., and Needleman A. Discrete dislocation plasticity: a simple planar model. Modeling Simul. Mater. Sci. Eng. 3 (1995) 689-735
39. Weppelmann E.R., Field J.S., and Swain M.V. J. Mater. Res. 8 (1993) 830
40. Yang E.H., and Fujika H. Reshaping of single-crystal silicon microstructures. Jpn. J. Appl. Phys. 38 (1999) 1580-1583
41. Yashiro K., Kurose F., Nakashima Y., Kubo K., Tomita Y., and Zbib H.M. Discrete dislocation dynamics simulation of cutting of γ′ precipitate and interfacial dislocation network in Ni-based superalloys. Int. J. Plasticity 22 4 (2006) 713-723
42. Yasutake K., Murakami J., Umeno M., and Kawabe H. Mechanical properties of heat treated CZ-Si wafers from brittle to ductile temperature range. Jpn. J. Appl. Phys. 21 5 (1982) L2-L88
43. Yonenaga I., and Sumine K. Dislocation dynamics in the plastic deformation of silicon crystals. Phys. Stat. Sol. A 50 (1978) 685
44. Zbib H.M., and Diaz de la Rubia T. A multiscale model of plasticity. Int. J. Plasticity 18 (2002) 1133-1163
45. Zbib H.M., Rhee M., and Hirth J.P. On plastic deformation and the dynamics of 3D dislocations. Int. J. Mech.Sci. 40 2-3 (1998) 113-127
46. Zbib H.M., Shehadeh M., Khan S.M., and Karami G. Multiscale dislocation dynamics plasticity. Int. J. Multiscale Comput. Eng. 1 (2003) 73-89
47. Zhang X.R., and Xu X. High precision microscale bending by pulsed and CW lasers. J. Manuf. Sci. Eng. Trans. ASME 12 3 (2003) 512-518
48. Zhang W., and Yao Y.L. Micro-scale laser shock processing of metallic components. ASME Trans. J. Manuf. Sci. Eng. 124 2 (2002) 369-378