Ultra-micro-indentation of silicon and compound semiconductors with spherical indenters

J. S. Williams; Y. Chen; J. Wong-Leung; A. Kerr; M. V. Swain

doi:10.1557/JMR.1999.0310

Ultra-micro-indentation of silicon and compound semiconductors with spherical indenters

J. S. Williams^*, Y. Chen, J. Wong-Leung, A. Kerr, M. V. Swain

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

91 Citations (Scopus)

Abstract

Details of microindentation of silicon, such as the semiconductor-to-metal transformation, which takes place on loading, have been examined using spherical indenters. Various forms of silicon are studied, including heavily boron-doped wafers and silicon damaged and amorphized by ion implantation as well as material containing dislocations. Results indicate that only silicon, which contains high concentrations of point defects or is amorphous, exhibits mechanical properties that differ significantly from undoped, defect-free crystal. Amorphous silicon exhibits plastic flow under low indentation pressures and does not appear to undergo phase transformation on loading and unloading. Indentation of compound semiconductors is also studied and the load/unload behavior at room temperature is quite different from that of silicon. Both gallium arsenide and indium phosphide, for example, undergo slip-induced plasticity above a critical load.

Original language	English
Pages (from-to)	2338-2343
Number of pages	6
Journal	Journal of Materials Research
Volume	14
Issue number	6
DOIs	https://doi.org/10.1557/JMR.1999.0310
Publication status	Published - Jun 1999

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AU - Williams, J. S.

AU - Chen, Y.

AU - Wong-Leung, J.

AU - Kerr, A.

AU - Swain, M. V.

PY - 1999/6

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AB - Details of microindentation of silicon, such as the semiconductor-to-metal transformation, which takes place on loading, have been examined using spherical indenters. Various forms of silicon are studied, including heavily boron-doped wafers and silicon damaged and amorphized by ion implantation as well as material containing dislocations. Results indicate that only silicon, which contains high concentrations of point defects or is amorphous, exhibits mechanical properties that differ significantly from undoped, defect-free crystal. Amorphous silicon exhibits plastic flow under low indentation pressures and does not appear to undergo phase transformation on loading and unloading. Indentation of compound semiconductors is also studied and the load/unload behavior at room temperature is quite different from that of silicon. Both gallium arsenide and indium phosphide, for example, undergo slip-induced plasticity above a critical load.

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Ultra-micro-indentation of silicon and compound semiconductors with spherical indenters

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