2.  Indentation-induced phase transformations in silicon as a function of history of unloading
                     / N. Fujisawa, R. Keikotlhaile, J. Bradby, J. S. Williams // J. Mater. Res. – 2008. – 23, № 10.
                     – P. 2645–2649.
                  3.  Transmission  electron  microscopy  of  amorphization  and  phase  transformation  beneath
                     indents in Si / H. Saka, A. Shimatani, M. Suganuma, Suprijadi // Phil. Mag. A. – 2002. – 82,
                     № 10. – P. 1971–1982.
                  4.  Contact resistance and phase transformation during nanoindentation of silicon / A. B. Mann,
                     D. Van Heerden, J. B. Pethica et al. // Phil. Mag. A. – 2002. – 82, № 10. – P. 1921–1930.
                  5.  Domnich V. and Gogotsi Yu. Phase transformations in silicon under contact loading // Rev.
                     Adv. Mater. Sci. – 2002. – 3. – P. 1–36.
                  6.  Khayyat M. M. O., Hasko D. G., and Chaudhri M. M. Effect of sample temperature on the
                     indentation-induced phase transitions in crystalline silicon // J. Appl. Phys. – 2007. – 101.
                     – P. 083515-1–083515-7.
                  7.  Temperature dependence of  silicon hardness:  experimental  evidence  of phase  transforma-
                     tions / V. Domnich, Y. Aratyn, W. M. Kriven, Y. Gogotsi // Rev. Adv. Mater. Sci. – 2008.
                     – 17. – P. 33–41.
                  8.  Understanding  pressure-induced  phase-transformation  behavior  in  silicon  through  in  situ
                     electrical probing under cyclic loading conditions / N. Fujisawa, S. Ruffell, J. E. Bradby et
                     al. // J. Appl. Phys. – 2009. – 105. – P. 106111-1–106111-3.
                  9.  Myshlyaev M. M., Nikitenko V. I., and Nesterenko V. I. Dislocation structure and macrosco-
                     pic  characteristics  of  plastic  deformation  at  creep  of  silicon  crystals  //  Phys.  Stat.  Sol.
                     – 1969. – 36, № 89. – P. 89–96.
                  10. Taylor T. A. and Barrett C. R. Creep and recovery of silicon single crystals // Mater. Sci.
                     Eng. – 1972. – 10. – P. 93–102.
                  11. Plastic deformation by shuffle dislocations in silicon / J. Rabier, M. F. Denanot, J. L. Deme-
                     net, P. Cordier // Mater. Sci. Eng. A. – 2004. – 387–389. – P. 124–128.
                  12. The difference of phase distributions in silicon after indentation with Berkovich and spheri-
                     cal indenters / I. Zarudi, L. C. Zhang, W. C. D. Cheong, T. X. Yu // Acta Mater. – 2005.
                     – 53. – P. 4795–4800.
                  13. Juliano T., Gogotsi Yu., and Domnich V. Effect of indentation unloading conditions on phase
                     transformation induced events in silicon // J. Mater. Res. – 2003. – 18, № 5. – P. 1192–1201.
                  14. On the dislocation mechanism of amorphization of Si by indentation / M. Tachi, Suprijadi,
                     S. Arai, H. Saka // Philos. Mag. Lett. – 2002. – 82, № 3. – P. 133–139.
                  15. Influence of loading holding time under quasistatic indentation on electrical properties and
                     phase transformations of silicon / O. Shikimaka, A. Prisacaru, L. Bruk et al. // Surf. Eng. and
                     Appl. Electrochem. – 2012. – 48, № 5. – P. 444–449.

                                                                             Received 27.03.2014






















                  106