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Nanoindentation Behaviour and Microstructural Evolution of Annealed Single-Crystal Silicon
Authors: Woei-Shyan Lee, Shuo-Ling Chang
Abstract:
The nanoindentation behaviour and phase transformation of annealed single-crystal silicon wafers are examined. The silicon specimens are annealed at temperatures of 250, 350 and 450ºC, respectively, for 15 minutes and are then indented to maximum loads of 30, 50 and 70 mN. The phase changes induced in the indented specimens are observed using transmission electron microscopy (TEM) and micro-Raman scattering spectroscopy (RSS). For all annealing temperatures, an elbow feature is observed in the unloading curve following indentation to a maximum load of 30 mN. Under higher loads of 50 mN and 70 mN, respectively, the elbow feature is replaced by a pop-out event. The elbow feature reveals a complete amorphous phase transformation within the indented zone, whereas the pop-out event indicates the formation of Si XII and Si III phases. The experimental results show that the formation of these crystalline silicon phases increases with an increasing annealing temperature and indentation load. The hardness and Young’s modulus both decrease as the annealing temperature and indentation load are increased.Keywords: Nanoindentation, silicon, phase transformation, amorphous, annealing.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1107149
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[1] S. G. Kaplan and L. M. Hanssen, “Silicon as a standard material for infrared reflectance and transmittance from 2 to 5,” Infrared Phys. Techno. 43, 389-396 (2002).
[2] W. C. Oliver and G. M. Pharr, “An improved technique for determining hardness and elastic modulus using load and displacement sensing indentation experiments,” Mater. Res. 7, 1564-1583 (1992).
[3] D. Beegan, S. Chowdhury and M. T. Laugier, “Work of indentation methods for determining copper film hardness,” Surf. Coat. Technol. 192, 57-63(2005).
[4] J. Z. Hu, L. D. Merkle, C. S. Menoni and I. L. Spain, “Crystal data for high-pressure phases of silicon,” Phys. Rev. B. 34, 4679-4684 (1986).
[5] I. Zarudi, L. C. Zhang, W. C. D. Cheong and T. X. Yu, “The difference of phase distribution in silicon after indentation with Berkovich and spherical indenters,” Acta Mater. 53, 4795-4800 (2005).
[6] W. C. D. Cheong and Zhang L .C., “Effect of repeated nano-indentations on the deformation in monocrystalline silicon,” Mater. Sci. Lett. 19, 439-442 (2000).
[7] J. Crain, G. J. Ackland, J. R. Maclean, R. O. Piltz, P. D. Hatton and G .S. Pawley,“Reversible pressure-induced structural transitions between metastable phases of silicon, ” Phys. Rev. B. 50,13043 (1994).
[8] J. Jang, M. J. Lance, S. Wen, T. Y. Tsui and G. M. Pharr, “Indentation-induced phase transformation in silicon: influences of load, rate and indenter angle on the transformation behaviour,” Acta Mater. 53, 1759-1770 (2005).
[9] Y. Gogots C. Baek, and F. Kirscht, “Raman microspectroscopy study of processing-induced phase transformations and residual stress in silicon,” Semicond. Sci. Technol. 14, 936-944 (1999).