Transmission electron microscopic observation of nanoindentations made on ductile-machined silicon wafers

Jiwang Yan; Hirokazu Takahashi; Jun'ichi Tamaki; Xiaohui Gai; Tsunemoto Kuriyagawa

doi:10.1063/1.2133908

Transmission electron microscopic observation of nanoindentations made on ductile-machined silicon wafers

Jiwang Yan, Hirokazu Takahashi, Jun'ichi Tamaki, Xiaohui Gai, Tsunemoto Kuriyagawa

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

40 Citations (Scopus)

Abstract

Nanoindentation tests were performed on a ductile-machined silicon wafer with a Berkovich diamond indenter, and the resulting indents were examined with a transmission electron microscope. It was found that the machining-induced subsurface amorphous layer undergoes significant plastic flow, and the microstructure of the indent depends on the indentation load. At a small load (∼20 mN), most of the indented region remains to be amorphous with minor crystalline nuclei; while under a large load (∼50 mN), the amorphous phase undergoes intensive recrystallization. The understanding and utilization of this phenomenon might be useful for improving the microscopic surface properties of silicon parts produced by a ductile machining process.

Original language	English
Article number	211901
Pages (from-to)	1-3
Number of pages	3
Journal	Applied Physics Letters
Volume	87
Issue number	21
DOIs	https://doi.org/10.1063/1.2133908
Publication status	Published - 2005
Externally published	Yes

ASJC Scopus subject areas

Physics and Astronomy (miscellaneous)

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10.1063/1.2133908

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abstract = "Nanoindentation tests were performed on a ductile-machined silicon wafer with a Berkovich diamond indenter, and the resulting indents were examined with a transmission electron microscope. It was found that the machining-induced subsurface amorphous layer undergoes significant plastic flow, and the microstructure of the indent depends on the indentation load. At a small load (∼20 mN), most of the indented region remains to be amorphous with minor crystalline nuclei; while under a large load (∼50 mN), the amorphous phase undergoes intensive recrystallization. The understanding and utilization of this phenomenon might be useful for improving the microscopic surface properties of silicon parts produced by a ductile machining process.",

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AU - Kuriyagawa, Tsunemoto

PY - 2005

Y1 - 2005

N2 - Nanoindentation tests were performed on a ductile-machined silicon wafer with a Berkovich diamond indenter, and the resulting indents were examined with a transmission electron microscope. It was found that the machining-induced subsurface amorphous layer undergoes significant plastic flow, and the microstructure of the indent depends on the indentation load. At a small load (∼20 mN), most of the indented region remains to be amorphous with minor crystalline nuclei; while under a large load (∼50 mN), the amorphous phase undergoes intensive recrystallization. The understanding and utilization of this phenomenon might be useful for improving the microscopic surface properties of silicon parts produced by a ductile machining process.

AB - Nanoindentation tests were performed on a ductile-machined silicon wafer with a Berkovich diamond indenter, and the resulting indents were examined with a transmission electron microscope. It was found that the machining-induced subsurface amorphous layer undergoes significant plastic flow, and the microstructure of the indent depends on the indentation load. At a small load (∼20 mN), most of the indented region remains to be amorphous with minor crystalline nuclei; while under a large load (∼50 mN), the amorphous phase undergoes intensive recrystallization. The understanding and utilization of this phenomenon might be useful for improving the microscopic surface properties of silicon parts produced by a ductile machining process.

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Transmission electron microscopic observation of nanoindentations made on ductile-machined silicon wafers

Abstract

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